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Home My WebLink AboutCT 81-16; Vista Santa Fe Phase II; Soils Report; 1983-06-08-- - -. __ - _. - - -. - - - - - -i - - l REPORT OF GEOTECHN I CAL I NVEST I GAT ION PHASE I I PROPOSED VISTA SANTA FE SUBDIVISION CARLSBAD, CALIFORNIA PREPARED FOR: RICK ENGINEERING 3088 Pio Pica Drive, Suite 202 Carlsbad, California 92008 PREPARED BY: SHEPARDSON ENGINEERING ASSOCIATES, INC. 1083 North Cuyamaca Street El Cajon, California 92020 DATE: Jpve 8. 1983 -, 1083 NORTH CUYAMACA STREET EL CAJON. CALIFORNIA QXJ’ZQ TELE: [ElQl44Q.Q830 June 6, 1993 Rick Engineering Company 3066 Pio Pica Drive, Suite 202 Carlsbad, California 92008 S.E.A. 110175 - - ATTENT I ON : Mr. Robert C. Ladwig SUBJECT: Report of Geotechnical investigation (Phase I I j, Proposed Vista Santa Fe Subdivision, C.T. 81-16, Carlsbad, California. Gentlemen: - In accordance with your authorisation, we have completed the subject investigation and herewith submit our findings, conclusions, and recom- mendations. The completion of the subject investigation is in conformance with the recommendations presented in our Phase I report on the subject project dated April 21, 1961. - The geotechnical data obtained during our Phase I Investigation has bean refined and incorporated into our current analysis and resulting recommendations presented in the body of this report. We have included herei n , as Appendix “A”, reproductions of the Phase I boring logs and laboratory data, to facilitate technical review of our recommendations. The recommendations presented herein are intended to supplement and, where applicable, supersede the recommendations presented in our Phase I report. The results of our investigations, completed as of this date, indicate that the subject site contains three significant geotechnical conditions which will require mitigation. A brief description of these conditions and our recommended concept for mitigation is as follows: 1) Existing Landslides Our investigation has revealed the presence of existing landslides within the subject site which are located within or adjacent to the proposed Improvements. We have utilized a conservative method of analysis of the available ,data to determine the need for, and scope of, appropriate mitigating measures. The recommendations eesented herein for mitigation of this condition, utilize the accepted, and time tested, method of regrading and/or stabilising buttress fills. - - 6EOTECHNICAL CONSULTANTS: ENGINEERS - 6EDLO6ISTS - - - - - - - - - - - June 8, 1983 -2- S.E.A. 110175 2) Expansive Soils The presence of moderate to critically expansive soils within the Del Mar Formation will require that mitigating measures be utilized to reduce the potential for damage to the proposed structures, as a result of the expansive characteristics of the foundation soils. The recommendations presented herein include selective grading to place a cap of low expansive soil on the building pads, as required. Low expansive material is available on the site for this purpose. We have also included recommendations for reinforced foundations, in the event sufficient quantities of low expansive materials are not available to provide capping material for all of the lots. 3) - Compressible Alluvial Deposits Our analysis of the alluvial deposits present within the north- northwest portion of the subject site indicate that mitigating measures will be required to improve the density of these deposits in their saturated conditions. Recommendations have been presented in the body of this report for the utilization of vertical drainage systems to accelerate the cosolidation of these deposits. Recommendations are presented In the body of this report which incorp- orate appropriate sections of the City of Carlsbad Grading Ordinance. In conclusion, it is our opinion that the subject site is suitable for the intended use, providing the recommendations presented heret n are incorporated in the design and construction of the proposed improvements and structures. Please do not hesitate to contact the undersigned, if you have any questions regarding this report. Respectfully submitted, SHEPARDSON ENGINEERING ASSOCIATES, INC. President. Vice Pnasldent l DES: jgr cc: ( 12) Addressee TABLE OF CONTENTS .- - INTENT . . L . . . . SCOPE . . . . . . . FINDINGS . . . . . . Site Description . Site Geology . . . Geomorphology . Geologic Units Torrey Sandstone Alluvium . . Colluvium . . Geologic Hazards . Landslides . . Seismicity . . Liquefaction . Groundwater . DISCUSSION . . . . . . General Soil Conditions Alluvial Deposits . . Liquefaction Potential Analyses of Existing Landslides De1 Mar Formation Subsurface Drainage Systems . . CONCLUSIONS & RECOMMENDATIONS . . . Site Preparation . . . . . Alluvial Soils . . . . Colluvial Areas . . . . Preparation of Natural Ground Transition Lots . . . . . * Earthwork . . . . . . . . Page No. 1 2 3 3 3 3 3 3 4 5 5 6 6 7 7 7 8 8 9 . 12 . 12 . 13 . 14 . 14 . 14 . 19 . 19 . 20 . 20 TABLE OF CONTENTS (Continued) Page No. i -~ - - - - - - - - Canyon Subdrains .............. 20 Landslide Mitigating Measures .......... 20 Slope Stability ............... 23 Landslide Debris Recompaction .......... 24 Slope Protection .............. 25 Cut-Off Drains & Canyon Drains .......... 25 Earthwork Factors .............. 26 Foundation Design Criteria ........... 27 General ................ 27 Specific ............... 27 Foundation Condition A ........... 28 Foundation Condition B ........... 28 Foundation Condition C ........... 30 Alternative Design-Condition C ....... 32 Foundation Condition D ........... 32 UNIFORMITY OF CONDITIONS & LIMITATION OF LIABILITY ..... 32 FIELD EXPLORATIONS ............... 33 LABORATORY TESTING ............... 34 ATTACHMENTS WEAKENED PLANE JOINT . . . . . MASTER SITE PLAN . . . . . . BORING LOGS . . . . . . . . TRENCH LOGS . . . . . . . . UNIFIED SOILS CLASSIFICATION CHART LABORATORY TEST RESULTS . . . . CROSS-SECTIONS . . . . . . . SLOPE DR&IN DETAILS . . . . . Plate Nos. ......... Figure "A" .......... 1 .......... 2-63 .......... 64-81 .......... N/A .......... 82-91 .......... 92-98 .......... 99 - - - - - - - - - - - - TABLE OF CONTENTS (Continued) APPENDICES APPENDIX "A" Boring Logs, Trench Logs 7 Laboratory Data - 1981 Report APPENDIX "B" Stability Analysis - Buttress Design APPENDIX "C" 30' Scale Grading Plans - Phase A Plate Nos. 1 - 8 . -- -. - - - - - - REPORT OF PHASE I I GEOTECHNICAL INVESTIGATION VISTA SANTA FE PROJECT LA COSTA AREAS SE18 - SE21 INTENT The intent of this investigation was to compile supplemental geotechnical data, as recommended in the Phase I Geotechnical Investigation for this project. Specifically, the Phase II Investigation was intended to: 1) 2) 3) 4) 5) Investigate the detailed configurations and stability of landslides within this project; Determine the extent and physical characteristics of the alluvial and col luvial materials and make recommendations with regard to required mitigating measures; Determine earthwork factors for the various materials which will be encountered during grading; Evaluate detailed grading plans with respect to soil conditions and; Refine recommendations and conclusions presented in the Phase I report. . - ._ June 8, 1963 -2- S.E.A. 110175 SCOPE - - - -~ - _.- - The scope of Phase I I of the Geotechnical Investigation for Vista Santa Fe has consisted of the following: 1) The extension of 15 small diameter test borings in the alluvial areas, at the locations shown on the attached Plate No. 1, as Boring Nos. 16 through 30. Representative, undisturbed soil samples were obtained from these borings and were returned to our laboratory for physical testing. 2) The extension of 32 large diameter test borings at the locations shown on the attached Plate No. 1, as Boring Nos. 31 through 62. The conditions encountered in these borings were logged utilising downhole inspection techniques by our engineering geologist. Selective soil samples were obtained from these borings and were returned to our laboratory for physical testing. 3) The extension of 39 backhoe trenches at the locations shown on the attached Plate No. 1. Representative soil samples were obtained from these test trenches and were returned to the laboratory for physical testing. 4) Laboratory tests were performed on representative samples of the soils encountered, in accordance with applicable ASTM procedures. In addition to the standard soil tests, time-rate consolidation tests were performed on representative samples of alluvial materials, and residual shear tests were performed on representative soils encountered in the zone of the existing slide planes. 5) Detailed engineering analyses were performed to determine rate and magnitude of potential settlement of the alluvial soils and stability . of the proposed grading, as ‘shown on 1 inch to 30 feet and 1 inch to 50 feet, grading plans for this project, prepared by Rick Engineering. - - June 8, 1983 -3- FINDINGS S.E.A. 110175 - - -. - - -- Site Description The boundaries and physical characteristics of the subject property have not been significantly modified since our Phase I report. An exception to this would be a series of crudely graded dirt access roads which were constructed in order to provide access for our dril I ing equipment. Site Geology Geomorphology: The subject site is characterised by an incised, generally westward sloping coastal plane, underlain by nearly flat lying sedimentary sandstone and mudstone beds. The major drainage channels in the area appear to have had a lower, older base level, as is evidenced by approximately 30 feet of alluvium within the major drainages. This lower, older base level is supported by similar alluvial deposits in numerous nearby creeks, rivers and lagoons. Under existing conditions, it appears that downward cutting of the major streams in the area is no longer an active process. Geologic Units: As was described in our Phase I report, the project site is underlain by four (4) mappable geologic units. These units consist of the: Del Mar Formation, Torrey Sandstone Formation, alluvium, and colluvium. Landslides are also mappable within the project, but are composed of materials from the Del Mar and Torrey Sandstone Formations. Del Mar Formation: The Del Mar Formation is the lowest unit, stratigraphically, exposed within the site and consists of green and greenish-brown claystone, siltstone and, near the contact with the overlying Torrey Sandstone, contains tan, medium to coarse sandstone beds. The Del Mar Formation is of Middle Eocene age . and was deposited in a generally brackish water, lagoonal environ- ment. Based on information obtained during this investigation, it June 8, 1983 -4- S.E.A.110175 - .- - - - -~ - - - -- - - - - appears that the bedding within the Del Mar Formation generally dips approximately 10’ toward the south. Portions of this formation were found to contain finely laminated siltstone-claystone beds, with occasional secondary gypsum crystals in the more porous zones and along fractures. Some of the claystone beds within the Del Mar Formation are extremely weak and there appears to be what has been termed “bedding plane shears” at some locations within these clay zones. Near surface materials of the Del Mar Formation are typically rather highly disturbed through weathering processes. It appears that alternate wetting and drying cycles and downhill creep are responsible for the major portion of this disturbance. This results in very weak soils in the approximately first 10 feet below the existing ground in areas underlain by the Del Mar Formation. Generally, this formation is rather impermeable. Most of the water we encountered within the formation was contained within the clean sandstone deposits, or in the fractures within the mudstone. Torrey Sandstone: The Torrey Sandstone conformably overlies the Del Mar Formation, generally above approximate elevation 240 msl at this site. This formation is characterised by cross bedded sandstone of Middle Eocene age, which represents a fossile barrier beach. It is composed of medium to coarse, buff to whitish-tan, clean sandstone with zones of iron staining which yield an orange color. This formation is generally free of mudstone interbeds above the 240 msl elevation. Typically, the Torrey Sandstone provides high strength material for the support of cut or fill slopes but may be susceptible to raveling type surface erosion due to its low cohesive properties. The sands within the Torrey Sandstone Formation are typically non-expansive in nature. - - June 8, 1983 -5- S.E.A. 110175 - - .- .- - - - - Alluvium: Generally, the alluvial materials we encountered within this project consist of partially consol idated to unconsolidated, brown to green-gray-brown, sandy clay. The maximum depth of alluvium within the major drainage along the north-northwest portion of the project is approximately 30 feet. The depth of alluvium in the smaller drainage along the south side of the project is considerably shallower, with a maximum depth on the order of 15 feet. It appears that the natural slope of the hillside must steepen rapidly, as it extends beneath the alluvium along the northern side of the project. Our test borings did not support a continu- ation of the adjacent hillside slope gradient beneath the alluvial materials. The alluvium along the north side of the project is almost totally saturated. We found that the depth to groundwater varied from zero to -3 feet below the existing ground surface in this alluvial area. No free water was encountered in the alluvium along the south side of the project, however, this condition could change, depending on the season of the year and varying rainfall. Colluvium: Our investigation indicates that the major deposits of colluvium within this project are along the south-southeast slopes. These colluvial deposits generally range in depth from 3 to 11 feet. The lower portions of the colluvium transitions into alluvium without a truly distinguishable interface. The colluvium is generally characterized by brown, sandy clay which is moderately compressible and expansive. The colluvial areas appear to consist of extremely weathered soil zones, which are in a state of creep, . and partial slopewash moving downslope. - _- June 6, 1983 -6- S.E.A. 110175 - - .- - Geologic Hazards Landslides: Our Phase I I Investigation has refined the limits and configurations of existing landslides within this project. The Phase I I Investigation reveals that slides within this project have a variety of configurations, ranging from shallow, rotational slump type failures to deep bedding plane glide failures. Generally, we found that the base of the sliding is considerably above the elevation of the canyon bottoms. This condition is rather unusual in that it has been our experience that lands1 ides with recognizable topographic expression normally extend down to or near the bottoms of adjacent canyons. The presence of the base of failure of many of these slides at higher elevations, indicates the presence of a weaker zone within the upper portions of the Del Mar Formation. The presence of weaker materials within the upper portion of the Del Mar Formation is further supported by fairly massive, recent landslides within the natural hillside comprising the easterly slope of the upper portion of the existing canyon along the proposed alignment of Mission Estancia within the southeast corner of the site. It is obvious that movement within these natural slides has occurred within the last 1 or 2 years. - - - .- - - The additional borings of Phase I I have not only revised the configur- ations of many of the original slides described in Phase I but have also resulted in the deletion or partial deletion of some of the previously suspected slides. This is due to the fact that the identification of slides in the Phase I report was typically based on topographic expression and evidence from a minimal number of test borings. At that time, if there was a question as to the possible presence of a slide, the conservative approach was taken so that preliminary designs for the project would also be conservative. The additional data available from Phase I I has allowed us to more accurately refine the presence and configurations of existing landslides. . June 8, 1963 -7- S.E.A. 110175 - - - - A detailed discussion of the stability of the landslides within this project is presented in this report under the “Conclusions 6 Recom- mendations” section. Seismicity: We encountered what appeared to be a normal fault within the Del Mar Formation in our test Boring No. 55. It is not uncommon to encounter inactive faults in this area. It is our opinion, based on existing geologic data, that the faults in the general area and within this project, do not pose a seismic threat and should not be a significant factor in the development of this project. However, we recommend that our engineering-geologist make periodic site inspections during the grading of this project to further evaluate and delineate the presence of faults. It is our opinion that the nearest source for a major earthquake which could affect this area would be the Elsinore or San Jacinto Fault Zones which lie approximately 25 and 35 miles, respectively, to the northeast. In our opinion, major earthquakes occurring along the Elsinore-San Jacinto Fault Zones could produce bedrock accelerations in the project area of approximately 0.16 g. Liquefaction: Due to the clayey, moderately dense nature of the existing alluvial materials within this project, it is our opinion that liquefaction in the event of a major earthquake would not be a potential hazard. Groundwater: Other than the saturated alluvium described above, our test borings encountered only isolated areas of groundwater, generally, within the more porous sandstone beds underlying this project. Although it appears that, other than the alluvial areas, groundwater elevations are sufficiently below the existing ground surface so that proposed grading should not intercept free water, it is possible that seepage from some pf the cut slopes constructed in the sandstone layers, may be - .- .- - - - - - - - -~ June 8, 1983 -a- S.E.A. 110175 encountered. Should seepage be encountered during the grading process, appropriate recommendations for the installation of subdrains in the seepage areas wil I be presented. DISCUSSION General Soil Conditions Our Phase I I Investigation has confirmed that essentially the entire site is overlain by a cover of clayey residual topsoi I which ranges in thickness from 1 to approximately 5 feet. Although the areas underlain by high quality sandstone have a thinner topsoil development, generally ranging in thickness from 1 to 3 feet, this topsoil contains substantial quantities of clay and should be considered expansive. Areas underlain by mudstone usually contain 3 to 5 feet of relatively soft topsoil materials. It should be anticipated that these topsoil materials will require densification prior to the placement of fill and will probably require removal from the top 3 feet of building pad areas. The previously described colluvial materials are considered moderately compressible and will require removal and recompaction during ~keying procedures for overlying fills. These colluvial materials range in thickness from approximately 3 to 11 feet, with the deeper portions occurring only in the extreme lower portion of the areas designated as colluvium on the attached Plate No. 1. It appears that materials within the landslide areas are not highly disturbed and therefore, we do not anticipate unusual settlement or compression in these areas. No deep slide graben deposits, typical of lands1 ide areas, were encountered or observed at the heads of the ancient landslides. However, detailed inspection during site grading should be performed to check for the presence of any undetected slide . graben deposits. June 8, 1983 -9- S.E.A. 110175 .- - - As was described previously, the Del Mar Formation is weathered severe1 y within the upper 10 feet of the existing ground surface and, therefore, may require deeper than normal keys for fills which are to be placed over existing hillsides. Furthermore, it appears that, at the toes of existing landslides,’ this weathering of the Del Mar Formation may be more extensive, requiring even deeper keys. - - An examination of the test borings located on the hillsides facing northwest in the western portion of the project, will reveal the presence - .~ - - of considerable quantities of non-expansive sandstone within the Del Mar Formation in this area. The sandstone beds in this area tend to be lenticular and range in thickness from 5 to 15 feet. The elevations of these beds would appear to make them accessible for mining as select material, if required. The mudstones and siltstones within the Del Mar Formation should be considered as highly expansive. Many of these beds exhibit considerable fracturing, with sl i kensided surfaces. Such features can detrimentally affect the stability of cut slopes constructed in these materials. Materials encountered within the Torrey Sandstone Formation, above approximately elevation 240 to 245 msl, appear to consist of fine to medium grained, silty to cohesionless, non-expansive sand, which should possess excel lent strength characteristics. This of course, does not include the thin clayey topsoil cover previously described. - - - - Alluvial Deposits In accordance with the recommendations contained in our Phase I report, we have obtained additional samples of the alluvial soils for laboratory testing and analysis. It is apparent that considerable settlement within the aJ luvial materials could occur beneath the proposed fills. The - June 8, 1983 -lO- S.E.A. 110175 - - - alluvial deposits located in the area of the north-northwest boundary of the subject site are essentially totally saturated, therefore an alter- native of removal and recompaction to mitigate potential excessive settlement in these alluvial deposits, does not appear viable. OUf subsurface investigations in alluvial deposits located along the southern boundary of the subject site did not, at the time of our investigation, encounter static groundwater, therefore, recommendations have been presented hereinafter for remova I and recompaction of the alluvial deposits along the southern boundary of the subject site in order to mitigate the settlement potential of the alluvium in that area. Our analysis of the time rate settlement characteristics of the saturated alluvium located along the north-northwest boundary of the subject site included performing consolidation tests on 7 samples, 5 of which were subjected to a series of five time rate consolidation tests each. The results of our testing and analysis indicate that the total settlement in the saturated alluvium will be in the order of 5 to 18 inches for fill depths ranging from 10 feet to 30 feet, respectively. Our analysis further indicates that the approximate time required to attain 90% consolidation under the maximum fi I I height, could be as great as 70 months. This estimate of time requires that a 1 to 2 foot drainage blanket of permeable material underlay all proposed fills. Time rate estimates of this type represent upper bound measurements and the actual consolidation time may be considerably less. Additionally, we have analyzed the reduction in the time required to achieve 90% consolidation as a l-es” It of the installation of vertical sand drains and/or surcharge loads. The number of drains required varies directly with each estimate of horizontal permeability used. The very minimum number of vertical drains needed would be one row situated at the toe of the proposed slope, -to provide a vertical path for horizontally moving water. _- - ..- - - - .- - - - -. .- June 8, 1983 S.E.A. 110175 However, the coefficient of horizontal permeability estimated for these studies cannot be accurately determined by normal laboratory testing procedures for these site conditions. Therefore, variations in the coefficient of horizontal permeability utilized in our time rate consoli- dation analysis can be expected to produce a significant error in the estimated time required to achieve 90% consolidation. Studies have shown that the optimum method of determining horizontal permeability is by conducting draw down/recovery pumping tests in the alluvial deposits. We have therefore presented recommendations hereinafter to conduct draw ,I down/recovery pumping tests in selected locations within the alluvia deposits along the north-northwest boundary of the subject site. The low permeabil,ity characteristics of the saturated alluvial soils wil I also mandate that the placement of fill in this area be at a controlled rate in order to prevent excessive increases in pore pressure and the possible resulting instability. The rate at which fill can be placed over the saturated alluvial deposits will be a function of the measures implemented to improve drainage characteristics of these deposits. Determinations of the rate at which fill can be placed on the alluvial deposits should be completed after data is obtained from the draw down/recovery pumping test described hereinafter and the determination of optimum spacing of the vertical sand drains, if utilized. The construction of a detention basin within the drainage course located near the north-northwest boundary of the site, wil I also affect the stability of the alluvial deposits underlying the proposed fills. The construction sequence utilized for the detention basin excavation should also be analyzed after the additional permeability data is obtained and a determination of the optimum spacing of the vertical sand drains, if utilized, has been completed. . - - - - - .-. - - June 8, 1983 -12- S.E.A. 110175 Liquefaction Potential: Based on the results of the Phase I I I nvesti- gation, and utilizing the simplified method for analyzing liquefaction potential described by Seed & Idriss, 1972, it does not appear that there is a significant potential for liquefaction within the alluvial soils of this project. The simplified method takes into consideration, average shear stress during an earthquake, significant stress cycles, relative density of the soils, grain size distribution of the soils, depth to water table, depth of overburden and ground acceleration. Our analysis indicates that the relatively fine grained nature of the alluvial soils, their relative density, and the moderate anticipated ground acceleration of . 16 9, are all factors which decrease the probability of liquefaction in these materials. Analyses of Existing Landslides The analyses we have performed on the stability of the existing landslides detected within this project were conducted utilizing the Bishop method. Soil strength determinations were obtained from labora- tory testing and, through back calculations assuming factors of safety equivalent to 1.0 for the slide masses under existing conditions. In our opinion, this method of analysis is appropriate and yet, conservative. It has been our experience, in working with landslide areas, that a conservative approach to stability analyses is appropriate due to the large number of variables which can affect the actual stability of the slide mass. Such variables include: - 1) Differences in soil strengths from location to location within the slide materials. 2) Differences in cross-sectional configuration throughout the slide. -. 3) A,lterations to the topography which may have occurred since the time of original landsliding. ,- - June 8, 1983 -13- S.E.A. 110175 - - - - - _. - - - - - - 4) Changes in hydrostatic pressures within the slide mass. Based on the calculations we have performed, we are of the opinion that, if the recommendations presented in this report are followed, all of the landslides detected within this project should have a long-term factor of safety against deep-seated movement in excess oft 1.5 and should have factors of safety sufficiently in excess of 1.0, even for the most severe short-term conditions. We wish to point out that there are obviously more risks involved in developing areas with existing landslides than areas without landslides. Our investigation, interpretations, and analyses of the existing land- slides on site, were done in accordance with the current standard of practice and are subject to the “Uniformity of Conditions and Limitation of Liability” section of this report. The results of our slope stability calculations are summarized in the attached Appendix “B”. Several of the existing landslide areas will require mitigating measures, as described under the “Recommendations” section of this report, in order to achieve an acceptable factor of safety. Subsurface Drainage Systems As was described previously, some areas of existing groundwater were encountered in O”t- test borings, principally in the porous sandstone materials within the site. Furthermore, the development of this area, as a residential neighborhood, will result in a rise in the amount of water infiltrating the ground surf ace and, thereby, could resu I t in an increase in groundwater elevation. We have, therefore, included in our recommendations, the installation of extensive subsurface drainage systems in virtually all areas of the existing landslides. Furthermore, in accordance with the City of Carlsbad Ordinance, Section 11.06.100 . .- - - - - June 8, 1983 -14- S.E.A. 110175 (3)B, we have also included recommendations for the installation of subdrains in all canyons to be filled. Although future seepage from sandy cut slope areas m=Y be encountered, in our opinion, it is virtually impossible, at this time, to predict where seeps will occur. Such seepage is normally considered a nuisance type problem and can be successfully treated in most cases, through the installation of subsurface drains. .- - - - Reference is made to the installation of cut-off drains, as shown on the attached Plate Nos. 92 through 98. The recommendation of cut-off drains and recompaction of native soils at the heads of slides in those areas where existing slide planes encounter proposed finish grade, are intended to achieve the following: 1)Reduce the potential for settlement in slide graben areas and ; 2)Reduce the potential for infiltration of surface water into the slide mass along the slide plane. CONCLUSIONS E* RECOMMENDATIONS Site Preparation Alluvial Soils: The alluvial deposits along the southern boundary of the subject site did not contain groundwater at the time of our investi- gation. Based on the assumption that groundwater will not be encountered fin these deposits at the time of site grading, we recommend that the alluvial deposits be removed to formational material, or to a depth which encounters alluvial deposits that possess a density of not less than 90% of maximum dry density, which ever is less, and be recompacted in accordance with the attached Grading Specifications. In the event the alluvial remova I encounters alluvial soils which possess the above described density, the contractor should be required to provide sufficient test trenches to permit testing of the alluvial deposit densities for an additional depth of not less than 10 feet. The . recommended 90% of maximum dry’ density should be present for the - - June 8, 1983 -15- S.E.A. 110175 - - - - .- .- .- .- - entire 10 feet of depth below the bottom of the excavation. The intent of this recommendation is to reduce the potential for future settlement due to concealment of low density soils beneath strata of alluvial deposits which possess a density equal to or greater than 90% of maximum dry density. The required density of the alluvial deposits may be reduced to 85% of maximum dry density outside of an imaginary line extending down and away from the rear of any proposed building pad, at a ratio of one unit horizontal to one unit vertical. In the event that groundwater is encountered in the alluvial deposits in this area, at the time of site grading, an addendum to this report will be submitted, presenting appropriate recommendations for densification of the alluvial deposits. Our analyses of laboratory test results obtained from representative samples of the alluvial deposits in the north-northwest area of the site have resulted in the following conclusions: 1) The consolidation characteristics of these deposits will produce settlements which are excessive in both magnitude and the time required to achieve 90% consolidation under the loads produced by the proposed structural fills. 2) The groundwater elevation at the time of our investigation and the groundwater conditions which we anticipate will exist at the time of site grading will, in practicality, prevent the mitigation of this adverse soil condition by removal and recompaction procedures. 3) The results of our time rate consolidation tests indicate a signifi- cant variation in the coefficient of vertical permeability. A review of the soil conditions encountered in our test borings indicates that substantial variation in the coefficient of horizontal permeability . will also exist. - - - -.. June 8, 1983 -16- S.E.A. i10175 - - I - - - .~ -- ..- .- - - - - 4) 5) 6) 7) The permeability characteristics of the alluvial deposits, as indicated by our field and laboratory data, require that detailed analyses and monitoring of the increase in pore pressure during construction of the structural fills be performed in order to reduce the potential for rotational type failures during construction. The risk of failures during construction can be reduced, although not eliminated, by a proper1 y designed instrumentatiorr program to monitor pore pressure increases during construction. The placement of “surcharge” fill loads will apparently have little affect on the reduction in time required to achieve 90% consolidation in areas where the proposed structural fill is in the order of 20 to 30 feet in height. A major decrease in the time required to achieve 90% consolidation can be achieved by the installation of vertical drainage systems. As was stated previously, our estimate of time required for consoli- dation, the need for and the design of vertical drains, and the problems with the rate of fill placement over saturated alluvial soils are all dependent on the permeability characteristics of the alluvial soils. The critical permeability with respect to the above may be the horizontal permeability of these soils. The accurate determination of horizontal permeability was beyond the scope of this investigation, since we did not foresee the critical need for determinations. We therefore have had to estimate horizontal permea- bility since, in our opinion, a realistic method of laboratory determination of this value was not available. In consideration of the magnitude of the effects horizontal permeability could have on the above factors, we are of the opinion that additional field investigations, consisting of pump draw down/recovery tests, are warranted. - - - .- .- - .- .- June 8, 1983 -17- S.E.A. 110175 .- - - . Laboratory consolidation test resu I ts were performed on representative samples under various loading conditions to determine the estimated maximum settlement and time required to achieve 90% consolidation. Our analysis of these results indicate that there may be a need to reduce the time required for the natural consolidation of the alluvial deposits. At this time, it appears that the most effective method of reducing the time frame is to reduce the distance that pore water must travel through the low permeability soils. The most commonly utilized procedure for accomplishing this reduction in drainage distance is the installation of a vertical drainage system in the alluvium, prior to placement of the proposed fill soils. We have, for the purposes of preparing preliminary cost estimates, analyzed the utilization of a drainage system consisting of vertical sand drains. We recommend that draw down/recovery pumping tests and additional analyses of alternative vertical drain systems be performed prior to commencing construction. The design procedures uti I ized in our vertical sand drain analyses follow the recommendations originally set forth by “Barron”. These recommendations were supported by numerous additional studies and texts we reviewed, one of the most recent of which was written by J.E. Bowles, 1982. We have, for the purposes of this preliminary study, estimated two different ratios of horizontal to vertical permeability. It is common knowledge that the horizontal permeability in alluvial deposits similar to that encountered in the subject site, will be greater than vertical permeability. The ratio of the permeability coefficients can best be determined by the above referenced draw down/recovery pumping tests. The results of our analyses, completed as of this date, utilizing a ratio of horizontal permeability equal to 5 and 10 times the vertical permeability, established by laboratory testing, is summarized in the following table. - - -. -. - - .- - June 8. 1983 -IS- S.E.A. 110175 Drain Drain 90% Trial Diameter Spacing Consolidation No (Ft.) (Ft.) Time (Days) lK horizontal K vertical (estimate) 1 1 8 60 5 2 1 10 60 10 3 2 9.3 60 5 4 2 12 60 10 5 1 11.3 120 5 6 2 13.1 120 5 7 2 17 120 10 a 1 14.1 120 10 1 Estimated horizontal to vertical permeability ratio to be verified by field testing. A review of the above preliminary estimates will show that the instal- lation of vertical sand drains, combined with a blanket of permeable sand over the existing alluvial soils, is a viable method of mitigating the extended time required to consolidate the existing alluvial deposits. It must be noted that these estimates are based on very conservative assumptions of the ratio of horizontal to vertical permeability which must be confirmed by adequate field testing. It must further be noted that, even if the total time required to achieve 90% consolidation is not a critical factor, the rate at which fill can be placed on the alluvial deposits, may control the time required to complete the proposed grading. In consideration of the costs involved in the installation of vertical drain systems, we recommend that the additional analysis of vertical drain -systems include a cost VS. ,time study. We are obviously aware that a portion of the proposed grading in Phase A, which will develop - - - -- - -,- - - June 8, 1993 -19- S.E.A. 110175 buildable lots, supported by structural fills placed over the alluvial deposits will incur significant cost for each day that rigid structures cannot be placed on these lots. We are further aware that the installation of improvements, i.e. streets, utilities, etc., proposed for this portion of Phase A, will be delayed and result in additional construction costs. It is therefore our opinion that additional information should be obtained to determine the relative magnitude of these costs in order to perform an effective cost/benefit study on the installation of vertical drains. Colluvial Areas: In consideration of the marginal density encountered in the colluvial deposits which cover a portion of the site, we recommend that the colluvial soils be removed to firm natural ground and replaced as structural fills in accordance with the attached Grading Specifi- cations. Firm natural ground is defined as soil which possesses an insitu density equal to or greater than 90% of its maximum dry density. We recommend that, for preliminary cost estimates only, an average depth of 5 feet be utilized for estimating the removal and recompaction requ i red in the colluvial area*. The actual depth of removal and recompaction may be substantially greater in localized areas. Preparation of Natural Ground: In addition to the removal and recom- paction of alluvial and/or colluvial soils, we recommend that all natural ground areas intended to receive structural fill, be scarified to a depth of not less than 12 inches and compacted to not less than 90% of maximum dry density, at approximately optimum moisture content. It should be noted that, in areas where the proposed fills will overlie existing topsoil, the topsoil may require removal and recompaction to depths ranging from 2 to 3 feet below existing grade. These topsoil materials must be removed to firm natural ground, defined as possessing an insitu density equal to or greater than 90% of maximum dry density. . -- - - - .~- - -. - - .- - - .~ June 8, 1983 -2o- S.E.A. 110175 Transition Lots: Foundations supported partially on cut and partially on fi I I are not recommended. The tendency of cut and fill soils to compress differently will probably result in unequal structural support and consequential cracking . Therefore, in transition areas, we recommend that the entire area be undercut and be replaced with soils compacted to a minimum of 90%. The undercutting should be carried to a depth of one foot below the base of the deepest footing. Earthwork : All earthwork and grading contemplated for site preparation should be accomp I ished in accordance with the attached Recommended Grading Specifications and Special Provisions. Utility trench backfill within 5 feet of the proposed structure and beneath asphalt pavement should be compacted to a minimum of 90%. The maximum dry density of each soi I type should be determined in accordance with ASTM Test Method 1557-79, Method A or C. Canyon Subdrains The approximate location of anticipated canyon subdrains is shown on the attached Plate No. 1. The canyon subdrains should be constructed in accordance with the details shown on Plate No. 98. - Landslide Mitigating Measures - As was discussed in the Phase I report, two methods of providing the - required stability for existing landslides within this project are to be utilized. These two methods consist of: 1)Stability provided by the proposed site grading and; 2)Stability provided by specially constructed stabilizing buttress fills. - In many of the existing lands1 ide areas, the proposed grading will provide the necessary stabilizing effect for the existing landslides due . to the placement of significant quantities of fill material at the toes of - June 8, 1983 S.E.A. 110175 these landslides and/or the removal of driving forces by cutting material from the heads of the slides. As was previously discussed, there does not appear to be highly disturbed materials within the landslide masses and it is therefore our opinion that treatment of existing slides to result in a factor of safety in excess of 1.5 against lateral instability is in accordance with the accepted standards of practice and should result in acceptable stability. The recommendations entitled “Cut-Off Drain lnstal lation” and “Landslide Debris Recompaction” described hereinafter must be incorporated into the grading plans to provide the required stability in landslide areas which are to be stabilized solely by the proposed site grading. The recommended locations, elevations, and configurations of proposed stabilising buttresses, required to provide the calculated factor of safety in excess of 1.5 against rejuvenated movement, are presented on the attached Plate Nos. 1 and 92 through 98, inclusive, and Appendix C. The concept of utilizing stability buttress fills to stabilize landslides is a well accepted procedure. It should be noted that exact elevations and widths of buttress fills may be refined during the grading of the recommended buttress keys. Depending upon the landslide configuration in relation tb the proposed grading, we have utilized both head and toe buttresses in our stability designs. Although the use of a head buttress provides stability for only part of an existing landslide, it is our opinion that, where recom- mended, the head buttresses are the most efficient method for providing the necessary stability for the proposed grading. A review of Plate ,No. 1 will indicate the approximate location of stabilizing buttress fills for the subject site. We have also shown the location of these buttress fills in more detail on the 30 scale grading plans prepared for Phase A, and included herein as Appendix C. The approximate cross-sectional config- . uration of the stabilizing buttress fills are shown on attached Plate - June 8. 1983 -22- S.E.A. 110175 - - - - - -- - - .- - - -. Nos. 92 through 98. Plate No. 98 presents our recommendations for typical subsurface drainage systems to be installed in each of the stabilizing buttress fills. The outlets of these subsurface drainage systems must be connected to suitable surface or storm drain facilities or drainage courses. The recommended stabilising buttress fills must be constructed from granular soils derived from the Torrey Sandstone Formation. our stability analyses utilized soil shear strength characteristics represented by 39’ angle of internal friction and zero cohesion. Such materials should be readily available from the Torrey Sandstone Formation. It should be noted that some of the cross-sections illustrating the recommended buttress fills utilize temporary. cut slopes at the rear of the buttresses which have slopes of one unit horizontal to one unit vertical. Although such temporary buttress cuts normally possess adequate short-term stability at this inclination, our experience has been that localized areas of construction failures in temporary buttress cut slopes should be expected. Furthermore, it should be pointed out that, during the butress construction process, the overall stability of any particular slide mass will be reduced to marginally stable conditions. It is possible that reactivation of a portion, or all, of a slide mass could occur during this period. We therefore recommend that the following construction procedures be followed in order to minimize the risk of landslide reactivation during grading: 1) No fill should be placed at the heads of slides prior to buttress construction. 2) Proposed cut areas at the heads of slides should be made prior to removal of material for buttress construction. . - June 8, 1983 -23- S.E.A. 110175 - - - - - - - - 3) Proposed fill areas which will overlie the toes, generally the lower half, of lands1 ides, should be made before any filling is done on the upper half. 4) Large buttresses should be constructed in sections so that not more than a 75 foot width of slide plane is exposed at any one time. Areas adjacent to the exposed section should be maintained a minimum of 10 feet in elevation above the slide plane, until the exposed section has been backfilled to a minimum of 10 feet above the slide plane. Slope Stability As was previously described, the Del Mar Formation contains areas of randomly oriented and often highly fractured zones containing slicken- sided surfaces, in addition to a generally low angle southerly bedding dip. Because of these characteristics, we recommend that detailed inspections of cut slopes be performed during the grading process by our engineering geologist. In the event that adverse dipping, IOW strenght bedding planes or highly fractured materials are exposed in the cut slopes, the installation of a facial buttress stability fill will be recommended. Such facial buttress fills will be approximately 20 feet in width and should contain the same buttress drain detail presented on the appatched Plate No. 99. In consideration of the shear strength characteristics of the prevailing Del Mar Formation soils and the probability that this geographic formation will be utilized to construct the majority of the proposed fill slopes, we recommend that slope subdrains be installed in all fill slopes in accordance with the details presented on attached Plate No. 99. A review of these details will iindicate that a~ slope drain is recommended - ..- . June 8, 1983 -24- S.E.A. 110175 - - -~ - -- - - - - - - in all fill slopes which are 20 feet in heigh~t, or greater. The expansive characteristics of Del Mar Formation clayey soils utilized to construct fill slopes will result in a gradual reduction of the in-place density of such soils with a corresponding increase in permeability. It has been our experience, during recent years of abnormally heavy rainfall, that surface slough type failures may occur in fill slopes constructed at an inclination of 2 units horizontal to 1 unit vertica, or steeper, within soils similar to the Del Mar Formation claystone and siltstone prevalent within the subject site. The intent of the recommended slope drains is to reduce the potential for accumulation of hydrostatic pressure in the near surface fill soils, thereby minimizing the potential for surficial failures. The slope stability recommendations for maximum cut and fill heights contained in our Phase 1 report are applicable. These recommendations are that cut and fill slopes constructed in or from, the Del Mar Formation materials at ratios of 2:1, expressed in horizontal to vertical units, be limited in height to 65 feet and 25 feet, respectively. Both cut and fil I slopes constructed from Torrey Sandstone materials, at slope ratios of 2:1, should be stable to heights in excess of 80 feet. Our examination of the proposed grading plans reveals numerous areas where fill slopes are in excess of 25 feet in height. In order to construct slopes to these heights and achieve a factor of safety of 1.5 against deep-seated failure, it will be necessary to control the quality of materials utilized to construct these slopes. We anticipate that mudstone-claystone Del Mar materials will not be permitted in the outer slope prism bounded by a line beginning 15 feet in from the top of slope and extending downward at a slope ratio of 1 :l. Lands1 ide Debris Recompaction Althoggh as previously described, our investigation did not encounter significantly disturbed deep zones within the slide debris materials, we - - .~ - - .- - June 8, 1983 -25- S.E.A. 110175 consider it prudent engineering practice to provide recompaction of landslide debris at the “head” and “toe” of existing landslides, where appropriate. A review of the areas recommended for removal and recompaction, as shown on Plate Nos. 92 through 98, will show that the majority of these areas will be removed during the installation of stabilizing buttress fills or the preparation of alluvial or colluvial deposits to receive structural fills. Slope Protect ion Slopes constructed from the sandy materials of the Torrey Sandstone Formation may be particularly susceptible to surface eras ion. We therefore recommend that a landscaping plan be initiated as soon as possible after the construction of fitI slopes within this project, which will resu I t in the establishment of a vegatative cover on the newly constructed slopes at the earliest possible date. In areas where it is anticipated that running water within the major drainage courses will contact fill slope materials, we recommend that adequate slope protection be included in the grading plan designs to provide erosion protection. Cut-Off Drains & Canyon Drains We recommend that subsurface cut-off drains be installed to intercept the flow of surface waters which may infiltrate the recompacted zones at the head of each landslide. The recommended location and configuration of each subdrain system is shown on the attached Plate Nos. 92 through 98 and Appendix “C”. We recommend that canyon subdrains be installed at the locations indicated on the attached Plate No. 1 and be constructed in accordance . with the details shown on Plate No. ‘98. - - - - - - - - - - 7 .- June 8, 1983 -26- S.E.A. 110175 Earthwork Factors Our preliminary calculations indicate the following information may be used for estimating the earthwork quantities for the Vista Santa Fe project. 1) 2) 3) 4) Assume all cut areas will have 2 feet of topsoil cover in which 1.0 cubic yard of cut wil I produce 0.86 cubic yard of compacted fill. In the remaining cut material (below 2 feet) 1.0 cubic yard of cut wil I produce 1.04 cubic yards of compacted fill. Assume all areas to receive fill, other than colluvial areas, will be recompacted during ground preparation so that they will loose approximately 0.4 feet. In other words, assume these areas will settle 0.4 feet when they are recompacted. Alluvial areas (Cal on maps) should be considered to settle according to the following table: Location Fill Height Total Settlement North 6 Northwest Area 30 Ft. 1.0 to 1.5 Ft. North & Northwest Area 20 Ft. 0.7 to 1.2 Ft. North 6+ Northwest Area 10 Ft. 0.4 to 0.8 Ft. South Area 40 Ft. 0.7 Ft. South Area 30 Ft. 0.6 Ft. South Area 20 Ft. 0.5 Ft. South Area 10 Ft. 0.3 Ft. 5) Colluvial areas (Osw on between 0.2 and 0.3 feet, . and recompaction. maps) shou I d as a result of be considered to settle the recommended remova I -- - -. - -, - - - .- - - - - - .- - - - -27- S.E.A. 110175 June 8, 1983 Foundation Design Criteria General: I” consideration of the potential for lateral movement of foundations constructed parallel to, and within 10 feet of, the top of any cut or fill slope within or constructed from the Del Mar Formation, we recommend that the following foundation design criteria be considered. 1) 2) 3) The depth of the foundation shall be sufficient to extend not less than 12 inches below a line parallel to and 5 feet in from the face of the slope. All foundations within 10 feet from the top of a slope shall contain not less than the rei nf orcemen t recommended in “Foundation Condition El”, described below, and be designed to support a maximum dead load of 1000 psf. All foundations within 10 feet of the top of a slope and parallel to the slope, should be tied into other foundations within the structures which are at least 20 feet from the top of slope. These cross ties should be constructed perpendicular to the top of slope, consist of at least a 12”x12” concrete beam, reinforced with two #4 bars, and be spaced at not greater than 15 feet intervals. The above recommendations are intended to supplement the requirements of Carlsbad Ordinance No. 8086, Section 11.06.110 for only those structures which are supported by Del Mar Formation soils. Specific: Due to the large quantity of expansive soil present within the subject site and the potential variation in the quantity of suitable non-expansive soils for capping the proposed structure areas, we recom- mend that provisions be made to install one of the following four . -- June 8, 1983 -28- S.E.A. 110175 -. -. alternative foundation recommendations. A detailed lot by lot survey will be performed upon completion of the site grading, with a report submitted which will present the recommended foundation condition classification for each lot. - ,.... Foundation Condition A: Each lot which receives this foundation classifi- cation designation must be underlain by soils which exhibit “low expansive potential”, i.e. expansion of less than 3%, when tested from an air dried to saturated condition, under a surcharge of 150 psf, for a depth of not less than 4.0 feet below proposed finish grade. In the event the structure area, i.e. the level lot pad extending from the front property line to a line which is not more than 15 feet from the rear of the level pad, contains soils which do not comply with the maximum 3% expansion, these soils shall be removed and rep I aced with “low expansive potential” soils. These low expansive materials shall extend to not less than 4.0 feet in depth. This condition can also be applied to fill lots where expansive materials are maintained at least 4.0 feet below a low expansive soil cap. - - - - Conventional spread footings may be used for foundation Condition A and should be founded a minimum of 12 and 18 inches below lowest adjacent grade, for one and two story structures, respectively, and have a minimum width of 12 inches. Spread footings may be designed for an allowable soil bearing pressure of 2,100 and 2,300 psf for 12 and 18 inch deep footings, respectively. Interior slab-on-grade should be not less than 4 inches in thickness, underlain by not less than 4 inches of clean sand or crushed rock, and completely surrounded by a continuous footing. Foundation Condition B: All lots which receive this foundation classifi- cation will possess expansive soils which exhibit an expansion of not . less than 3% nor more than 8%,’ when tested from an air dried to June 8, 1983 S.E.A. 110175 - - - .~- - .- - - saturated condition, under a surcharge load of 150 psf. These soils will be examined for a depth of not less than 4 feet below finish grade. 1) Al I footings should be founded a minimum of 18 inches below adjacent finish grade and may be designed for an allowable soil bearing pressure of 2,200 psf. Footings should have a minimum width or diameter of 12 inches. 2) Both exterior and interior continuous footings should be reinforced with one #4 bar, positioned 3 inches above the bottom of the footings and one #4 bar positioned one inch clear below finish floor or the cold joint between the foundation and slab pour. Pier footings need not be reinforced. 3) Interior slabs should be a minimum of 4 inches in thickness and underlain by a 4 inch blanket of clean sand or crushed rock. Further, interior slabs should be reinforced with 6”x6”-10/10 welded wire mesh and completely surrounded with a continuous footing. 4) Exterior slabs should be a minimum of 4 inches in thickness and constructed on native soils prepared in accordance with the recommendations presented in Item No. 6 shown below. Further, exterior slabs should be reinforced with 6”x6’‘-lo/10 welded wire mesh and be provided with weakened plane joints, as recommended hereinafter. 5) Weakened plane joints for exterior slabs should be provided for any slab greater than 5 feet in width. Any slabs between 5 and 10 feet should be provided with a longitudinal weakened plane joint at its center line. Slabs exceeding 10 feet in width should be provided with a weakened plane joint located 3 feet inside the June 8, 1983 -3o- S.E.A. 110175 - - - - - - - .-. - 6) 7) ‘3) exterior perimeter, as indicated on the attached Figure A. Both transverse and longitudinal weakened plane joints should be con- structed as detailed on Figure A. Clayey soils should not be allowed to dry before placing concrete. They should be sprinkled, if necessary, to insure that the soils are kept in a very moist condition or at a moisture content exceeding 2% above optimum moisture content. Surf ace drainage should be directed away from the proposed foundation. Prior to pouring concrete, the foundation excavations should be inspected by a representative of this office, to insure that the above recommendations have been followed. Foundation Condition C: All lots which receive this foundation condition classification will contain expansive soils which exhibit an expansion of not less than 8%, nor more than 12%, when tested from an air dried to saturated condition under a surcharge load of 150 psf. The soils will be examined for a depth of 4 feet below finish grade. 1) Al I footings should be founded a minimum of 24 inches below adjacent finish grade and may be designed for an allowable soil bearing pressure of 2,000 psf. Footings should have a minimum width or diameter of 12 inches. 2) Both exterior and interior continuous footings should be reinforced with two #4 bars positioned 3 inches above the bottom of the footings and two #4 bars positioned one inch clear below finish floor or below the cold joint below the foundation and slab pour. yier footings need not be rei “forced, although exterior piers should extend not less than 3 feet below adjacent grade. - - - - June 8, 1983 -31- S.E.A. 110175 3) 4) 5) 6) 7) 8) Interior slabs should be a minimum of 4 inches in thickness and underlain by a 6 inch blanket of crushed rock. Further, interior slabs should be reinforced with 6”x6’l-6/6 welded wire mesh and completely surrounded with a continuous footing. Exterior slabs should be a minimum of 4 inches in thickness and constructed on native soils prepared in accordance with the recommendations presented in item No. 6 shown below. Further, exterior slabs should be reinforced with 6”x6”-lo/10 welded wire mesh and be provided with weakened plane joints, as recommended hereinafter. Weakened plane joints for exterior slabs should be provided for any slab greater than 5 feet in width. Any slabs between 5 and 10 feet should be provided with a longitudinal weakened plane joint at its center line. Slabs exceeding 10 feet in width should be provided with a weakened plane joint located 3 feet inside the exterior perimeter, as indicated on the attached Figure A. Both transverse and longitudinal weakened plane joints should be constructed as detailed on Figure A. Clayey soils should not be allowed to dry before placing concrete. They should be sprinkled, if necessary, to insure that the soils are kept in a very moist condition or at a moisture content exceeding 2% above optimum moisture content. Surface drainage should be directed away from the proposed foundation. Prior to pouring concrete, the foundation excavations should be inspected by a representative of this office, to insure that the above recommendations have been followed. . - - - ,- - - - - - - -. - - June 8, 1983 -32- S.E.A. 110175 Alternative Design - Foundation Condition C: An alternate pre- stressed concrete foundation and slab design for soil Condition “C” may be utilised. This design should be prepared by a Registered Civil Engineer experienced in the design of pre-stressed concrete structures. The preparation of the foundation soils and detailed recommendations regarding foundation construction and pre- stressing requirements should be prepared in cooperation with your structural design consultant. Exterior slabs should be prepared as described in Foundation Condition “C” above. Foundation Condition D: All lots which contain soils within 4 feet of finish grade that exhibit an expansion greater than 12%, should be regraded to remove the critically expansive soils. Adjacent footings founded at different bearing levels should be so located that the slope from bearing level to bearing level is flatter than one unit horizontal to one unit vertical. The allowable soil bearing pressures described above may be increased by one-third for wind and/or seismic loading and should be decreased by one-fourth for dead loads only. UNIFORMITY OF CONDITIONS S LIMITATION OF LIABILITY 1) The conclusions and recommendations presented in this report are based upon the assumption that the soil conditions do not deviate appreciably from those disclosed by the subsurface investigations. If variations are encountered during construction, we should be notified so that we may make supplemental recommendations, if this should be required. . June 8, 1983 -33- S.E.A. 110175 - .- .- ,- - - - - - - - - 2) Evaluation and utilization of the soil materials for the support of the proposed structures includes investigation of the subsurface conditions, analysis, formulation of recommendations and inspection during grading. The soil investigation is not completed until the soil engineer has been able to examine the soil in the excavations so that he may make the necessary modifications, as needed. We emphasize the importance of the soil engineer continuing his services through the inspection of grading, including construction of fil I and foundation excavation. 3) The findings of this report are valid as of the present date. However, changes in the condition of a property can occur with the passage of time, whether they be due to natural processes, or the works of man on this or adjacent properties. In addition, changes in applicable or appropriate standards occur, whether they result from legislation or the broadening of knowledge. Accordingly, the findings of this report may be invalidated, wholly or partially, by changes outside of our control. Therefore, this report is subject to review and should not be relied upon after a period of three years. FIELD EXPLORATIONS Eighty seven subsurface explorations were made at the locations indicated on the attached Plate No. 1 between May 25, 1982 and June 11, 1982. These explorations consisted of borings drilled by means of a rotary bucket and rotary auger type drill rigs and trenches dug by means of a backhoe. The explorations were conducted under the observation of our engineering geology personnel. The explorations were carefully logged when made. These logs are presented on the following Plate Nos. 2 through 81. The soils are . - - - - - - - - - - - - - June 8, 1983 -34- S.E.A. 110175 described in accordance with the Unified Soils Classification System, as illustrated on the attached simplified chart. In addition, a verba I textural description, the wet color, the apparent moisture, and the density or consistency~ are given on the logs. Soil densities for granular soils are given as either very loose, loose, medium dense, dense, or very dense. The consistency of silts or clays is given as either very soft, soft, medium stiff, stiff, very stiff, or hard. Representative core samples of the alluvial materials were obtained by means of a split tube sampler driven into the soil by means of a 140 pound weight free falling a distance of 30 inches. The number of blows required to drive the split tube sampler is indicated on the boring logs as “blows per foot.” The core samples were carefully removed, sealed, and returned to the laboratory for testing. Disturbed and undisturbed samples of typical and representative soils were also obtained and returned to the laboratory for testing. LABORATORY TEST~I NG Laboratory tests were performed in accordance with generally accepted American Society for Testing and Materials (A.S.T.M.,) test methods or suggested procedures. Representative samples were tested for their compressiblity., expansive potential, maximum density and optimum moisture content, in-place density and natural moisture content, angle of internal friction and cohesion intercept. The results of these tests are presented on Plate Nos. 82 through 91. The expansive potential of clayey soils was determined in accordance with the following test procedure. . - - - - - - - - - - - June 8, 1983 -35- S.E.A. 110175 Allow the trimmed, remolded or undisturbed sample to air dry to a constant moisture content, at a temperature of 100’ F. Place the dried sample in the consolidometer and allow to compress under a load of 150 psf. Allow moisture to contact the sample and measure its expansion from an air dried to saturated condition. . - - J - Wk loQ.p~ 0 + 3- - 0 - 3- 1 t -'w*50- LIOQ + w/2 t w/2 1 TYP. SAW CUT FILL WITH FLEXIBLE CRACK FILLING COMPOUND L?teqElFrn (AS f&?COMMEffDED IA REPORT -TYP.) VISTA SANTA FE SHEPARDSON ENGINEERING ABsocIpLTE8. Inc. WEAKEND PLANE JOINT DETAIL r-82 110175 I , Fl$$,,RE ,:‘A” .._ .,- - _. - - - .- - - - - - - & I I . 82 i2 i :L F A ,L :L su su BORING NO. B I6 BORING NO. B I6 LEVATION: ‘lo+ LEVATION: ‘lo+ BORING DIA. BORING DIA. DESCRIPTION DESCRIPTION “cry Dark Gray, Wet tc Saturated, Soft, Clay Water Table 1 Rrown Gtay, Medium Stiff, Sandy Clay Lighter Brown Gray & Green, Saturated \ \ Gray Green, Saturated, Medium Stiff, Sandy Ctay 1, Yellow Green, Saturated, Medium Stiff, Sandy Clay \ END OF BORING _-- Bulw COUNT - K - 3" O.D. Sampler. Kelly bar of drill rig 1.9 8.9 2.6 drop II per-bfti. L - 3'? O.D. Sampler, 1401b. hammer, 30" drop S - Stan&q-d P&&meter SAMPLE TYPE U = Undisturbed Drive Smple C -.Chunk Sample B -,Bulk Sample -,~ -~ - -_ - - .,.. ,- - - - - - - - - 1: I I . hZ i2 i L ii H - L - L - . .-- - g K = 3" O.D. Sampler, Kelly bar of drill rig I E 1' per blow. & 3 [ 7 4 f \ \ \ \ 1 \ SI BORIN% BORIN% B 17 NO, - NO, - ELEVATION: 11*+ BORING DIA. BORING DIA. 6" DESCRIPTION lark Gray, Wet, Soft, Clay --------m-m :reen Gray, Wet to Saturated, Soft, Clay illuvium 9, Water Table green Gray, Wet to Seturated, Medium to Soft, Very Sandy :1ay rlluvium :reen, Wet, Stiff, Mudstone - De1 Mar Farmetion END OF BC;RING 1 3; ;‘ ;: i[ i 1.5 ii. I i in [~ ! r ‘5 ‘5 ._“__. ..---, -- = Standard Penetrweter SAMPLE TYPE - _--- ___- -_-_ U - Undisturbed Drive Sam ,ple C =. Chunk Saw )le I^ B - Bulk Sampi, VISTA SANTA FE KIS I 5/25/a, I D1~AT.E NO. 3 - -~ -. ,- - .- - - - - .- - - .- 2- 1 ULI t,- B& 6- a- 1 UL! 0- 2- 41 IJLI 6- 8- 1 UD o- 2- 4- 6 1 UD a- 0- -I ULI 2- 4- ~~~~~-~~~~-- ay Brown Mottled Orange & Yellow, Wet to Saturated, dim Stiff, Clay Greer. Gray, Wet to Saturated, Medium Stiff, Clay Blue Gray, Saturated, Stiff, Clay De1 Mzr Formation END OF BORING BLOW COUNT - -a - K - 3" O.D. Sampler, Kelly bar of drill rig drop 1' per blow. 2 5: ;’ 2: 9 Y :IL 31 61 3L ‘31 ;I r it :* ;; :: I /.z S = Standard Penetrometer SAMPLE TYPE U = Undisturbed Drive Sample C =.Chunk Sample B = Bulk Sample ,’ m- ,- - - - - - - - .- - - 1 1 1 1 1 2 2 2 2 2 3 3 3 3 I - Gray, Wet, Saturated, CLay, Alluvium Water Table ---v--m----- Gray 8 Brown Mottled Red, Wet to Saturated, Medium Stiff, Gravel in Clay, Alluvium ------ ---- reen Gray, Saturated, Medium Stiff, Sandy Clay -----w-m--- Brown Gray, Gravel in Clay -------m---e reen Gray, Saturated, Medial Stiff, Clay Sandy Clay Blue Green, Saturated, Stiff, Clay, De1 Mar Fcrmation END OF BCiRING BLOW COUNT - EC K = 3" O.D. Sampler, Kelly bar of drill rig drop 1' per blow. L - 3'( O.D. Sampler, 1401b. hammer, 30" drop S = Standard Penetrometer SAMPLE TYPE U = Undisturbed Drive Sample C =. Chunk Sample B - Bulk Sample - ,- - - - - - - - ..- - - - 2- 4- 61 UD 8- 10 - L2- 14- L6=" 18- !C' 12 - !L- !61 UD 8- o- 1 UD 2- 4- 6- ;I ! c ! s f \ - \ \ \ \ \ \ \ \ \ \ \ t ‘\ L SI BORING NO, B 2o BORING DIA, DESCRIPTION Brown Gray, Wet tc Saturated, Soft to Medium, Sandy Clay Alluvium ---- - s Water Table Grave 1 Some Gravel Gray & Yellow Brown, Soft, Medium Stiff, Clay & Sandy Clay Green & Yellow Brown, Sandy Clay, De1 Mar Formation EAD OF BORING SLOW COUNT * _I K - 3" O.D. Sampler, Kelly bar of drill rig drop 1’ per blow. 2 i; ;’ 1: > fL bl 9L L = 3'! O.D. Sampler, 1401b. hammer, 30" drop SNEPMDSON ENOWEERlNG ASSOCIATES INC. S = Standard Penetrometer SAMPLE TYPE II = Undisturbed Drive Sample C =~Chunk Sample B = Bulk Sample - .- ,-.. .- - .- - .- - - - - - .- - .- I; . G 2 ;T H -. ss HI C H BORING DIA. DESCRIPTION Dark Blue Gray, Wet to Saturated, Soft, Clay, Alluvium n Water Table -ms Dark Green Gray, -----m-e- Saturated, Medium Stiff, Gravel in Clay Green Gray & Orange, Saturated, Medium Stiff, Clay Alluvium Gray, Saturated, Dense, Gravel in Clay Matrix Green & Yellow, Moist to Wet, Dense, Clayey Sandstone De1 Mar Formation I END OF BORING Yuv I a 1. , t 1: > 5L 51 is .?l bl YL BLOW COUN'I! - _I K = 3" O.D. Samoler. Kellv bar of drill rin I 1’ per'blo)r. - .D. Sagplet, 14Qlb. hammer, 30" drop dard Penetrometer WE9MDSON ENGINEERING - .~~. - - - ,~- - - - - - - - - - - .- - SI SI BORING NO, B ** BORING NO, B ** BORING DIA. BORING DIA. DESCRIPTION DESCRIPTION Dark Brown Gray, Wet to Saturated, Soft, Clay -- - Water Table Gray Brown, Saturated, Medium Stiff, Clay Alluvium be,.:- --- ----m-m, ?>:i Or-an&e Tan, Saturated, Very Cerise, Clayey Sandstone, De1 Mar Formation EKD OF BORING 2 ;. , , ;’ 1 IL -r 2: :r: :i gt ‘i r m BLOWCOti - K - 3" O.D. Sampler. Kelly bar of drill rig drop 1’ per-bl&. - E L = 3'! O.D. Samoler. 1401b. hanrmer. - I 30” drOD SNEPARDSON U'JOlNEERlNG AsoaMEs. INC. 6 = Standard Pyenetr&eter SAMPLE TYPE u = Undisturbed Drive Sample C r.Chunk Sample 'B - Bulk Sample - - - - - - - - - - - - - - 2- 1 UD 4- 6- aA “D 0- 2- 4AUD 5- 3- 1 UD I- BORING NO, DESCRIPTION =I I ‘IA IW iz I i L Light Brown, Wet, Medium Stiff, Sandy Clay Alluvium M L. )z”-: Tan, Wet, Medium Dense, Silty Sand \ Light Brown to Green Gray Brown, Wet, Medium Stiff, Clay Alluvium i \Gray Green, Wst,Mediumto Stiff, Sandy Clay De1 Mar Formation _ g Water Table - - END OF BORING 2! 1; 1. :I I ’ I !: i 1.1 ILOW COUNT - *-. - K - 3" O.D. Sampler, Kelly bar of drill rig drop, II per blow. L - 3'! O.D. Sampler, 1401b. hammer, 30" drop 8IIEPAWSONENOWEBWNG Asoa4lEs. INC. S = Standard Penetrometer CAMPLE TYPE VISTA SANTA FE U - Undisturbed Drive Sample g =.ghu+Samp: - - ,-, - - - - - - -. - - - - - - - 2- 4- 6AUD a- 0-. 2- 4- 6 1 UD 8- 0- 2- 4- 6l 0- 1 I 1 . >E 3 k M - ,L, -. - L .- :L .- L BORING NO, - ELEVATION : - DESCRIPTION Brown, Wet, Soft, Clay Brown to Tan, Wet to Saturated, Medium Stiff, Sandy Clay Water Table \ IPink Brown, Wet to Saturated, Medium Stiff, Very Sandy ++h---------, ---.- - ---I Light Brown Mottled Maroon & Yellcw, Probably Weathered De1 Mar Formation __------------- Light Green Mottled Maroon, Wet, Stiff, Clay De1 Mar Mudstone \ END OF BORING -. .~~, .~ ,.. - .- - - -~ - - - - - - -~ I! . ,” 2 L .- - H - BORING NO, ELEVATION: 129+ -BORING DIA, 6" DESCRIPTION ,\I Dark Gray Brown, Wet, Medium Stiff, Clay \ Dark Gray Brown, Wet, Medium Stiff, Clay Alluvium - QSW Alluvium - QSW p Water Table Water Table -- Y Brown, Wet, Very Stiff to Hard, Pure Mudstone \ De1 Mar Formation Brown, Wet, Very Stiff to Hard, Pure Mudstone De1 Mar Formation END OF BORING BLOW COUNT l - K = 3" O.D. Saumler. Kellv bar of drill rig I E drop, 1’ per-blow. - - I L = 3” O.D. Samuler. 1401b. hamer. 30” droo SNEPANDSON ENGINEENING -lEs. INC. S = Standard Penetr&neter SAMPLE TYPE u - Undisturbed Drive Sample C =.Chunk Sample B = Bulk Sample - ,.- ._ - _~- - - ,. - - - - - - - SU BORING NO, B 26 14’+ BORING DIA, DESCRIPTION Dark Brown Gray, Wet, Medium Stiff, Clay QSW Dark Gray Green, Moist to Wet, Stiff to Hard, Sandy Clay De1 Mar Formation END OF BORING BLOW COUNT - KEY - I K - 3" O.D. Sampler, Kelly bar of drill rig E drop, 1’ per blow. I- - L = 3'! O.D. Sampler, 1401b. hsmmer, 30" drop SMEPMDSON ENGINEERING AswxmlE.s. INC. S = Standard ~enetrameter SAMPLE TYPE VISTA SANTA FE U - Undisturbed Drive Sample C =.Chunk Sample KLS I 5/i7/82 B = Bulk Sample 110175 PLATE NO. 12 - -- - - ,- - - - - - - - - - - r - su BORING NO, B 27 ELEVATION: 136: BORING DIA, DESCRIPTION Green Brown, WeZ, Medium to Stiff, Sandy Clay QS$ Alluvium No Water Tan Brown, Moist, Stiff to Hard, De1 Mar - Mudstone END OF BORING BLOW COUNT - K = 3" O.D. Sampler, Kelly bar of drill rig drops 1’ per blow. L = 3'! O.D. Sampler, 1401b. hammer, 30" drop SNEPARLSON ENGINEERING A.ssouAlEs. INC. S - Standard Penetrometer SAMPLE TYPE u - Undisturbed Drive Sample VISTA SANTA FE C =.Chunk Sample KLS 1 5127182 B = Bulk Sample 110175 PLATE NO. 13 - 2- 4- 4 UI 6- a- 0- 4 IJI 2- 4- 6- a- o- 1 1 1 . p 12 L :L s- C mm L FT - :L - B 28 BORING NO, - LEVATION: 135’ BORING DIA, DESCRIPTION ,\ Dark Gray Brown, Moist, Medium Stiff, Clay \ Gravelly Alluvium m--------m- Be-- Brown, Moist to Wet, Stiff, Gravelly. Clay, Alluvium ---------w-P-- Gray Green Mottled Maroon, Moist to Wet, Stiff, Clay, Probably Weathered De1 Mar ; J”:‘Red & Yellow, Wet, Stiff, Gravel in a Clay Matrix, Bright Leo Colors \ Light Gray Mottled Maroon & Yellow, Moist to Wet, Hard, Clay \ De1 Mar Formation END OF BORING r I. jI fi u K ‘L -I r 3* . . I: ;: 1 2.1 BLOW COUNT - su BORING NO. - B 29 125+ BORING DIA, “’ DESCRIPTION 6- 8- o- JI UD 2- lluvium- Water Table 01 !/2 w 6- 8- 0- J UD 2- ------------- n Gray, Saturated, Loose, Clayey Sand - Probably,.Just a Thin Len% - None on Augers ZL 6- 8- 0 UD ---------mm- -- FL 2- ay Green Mottled Yellow, Wet, Stiff to Hard, Sandy Clay De1 Mar Formation 6- UD 3; I I END OF BORING YPY nEI I BLOW COUNT - K - 3” O.D. Sampler, Kelly bar of drill rig drop, 1' per blow. L - 3" O.D. Sampler, 1401b. hammer, 30" drop SHEPARDSON ENGINEERING ASSOCIATLS. INC. S - Standard Penetrweter SAMPLE TYPE VISTA SANTA FE U - Undisturbed Drive Sample C -,Chunk Sample KLS I 5127182 B - Bulk Sample 110175 PLATE NO. 15 - -- - - - - - - - .- - - - - I su 4 I s lil WE I . -BORING DIA. i: -$ g 1z-i ii3 ;' 1: !2 - i DESCRIPTION , L Brown Gray, Wet, Soft, Clay Alluvium 2- 4- -- Groundwater 64”’ 'L a- -. .--- ---w----v L Blue Gray & Yellow Brown to Light Green Gray Mottled Orange, 0- Wet, Stiff to Soft, Sandy Clay 1 UD \Y OL Alluvium 2- Very Sandy Clay 6 1 “D IL a- o- 1 UD FA !J.c 2- 61 UD - \\ 2 ,c v‘; Bright Orange-Yellow-Red In Green Gray,Snturated Dense Gravel a- Y”,: in Clayey Sand-Sandy Clay ,\:, Alluvium 0- .I 2- i\” T \IBlue Gray & Pink Brown, Wet, Stiff to Hard, Mudstone 4- H “De1 Mar Formation - 6- END OF BORING UL BLOW COUNT - K - 3" O.D. Sampler, Kelly bar of drill rig drop 1' per blow. L = 3" O.D. Sampler, 1401b. hammer, 30" drop SNEPARDSON ENGlNEElUNG AssmlAlEs. INC. S = Standard Penetrometer SAMPLE TYPE VISTA SANTA FE U I Undisturbed Drive Sample C =.Chunk Sample KLS I 5f27182 B = Bulk Sample 110175 PLATE NO. 16 -~ ,-. - .- - - - - - - - - - .- - - - 2- 4- 6- a- o- 2- 4- 6- a- o- 2- 4- 6- a- o- 2- 4- 6,CK su I loI‘ BORING NO, B 31 DESCRIPTION I h 1 C/ .,ss:,..l Tan & Orange to Buff, Moist, Medium to Dense, Very Fine v v. Clayey Sand - Sandy Clay to Fine Silty Sand b $. .j.: $.,I~ L/ !'#.:i Blue Gray to Light Green, Moist, Medium to Stiff, Sandy M 'C { Siltstones with Concretions ; 1; :I, 4.1. .; 1. Ii*, ., I.1 t M :I:'.!; Buff, Moist, Medium to Dense, Clean Sandstone ; .i: :f: ‘1 .I:' ;I.;. ,If $I>. ./i : ,; 4 ,.i:: : VATION: lz9' -BORING DIA, 30” M/ ,I;:If:Buff to Yellow Tan, Saturated, Dense, Sandstone, Seepage, C d;'!Severe Seepage from This Zone M :.'y; ;:I: i. ;t.:.- \ \ _.-_ BLOW COUNT - K - 3" O.D. Sampler, Kelly bar of drill rig drop 1’ per blow. L = 3" O.D. Sampler, 1401b. hammer, 30" drop S = Standard Penetrometer SAMPLE TYPE u = Undisturbed Drive Sample C = Chunk Sample VISTA SANTA FE G- 2- 4- 6- BORING NO, B 31 (Cont'd) -BORING DIA. DESCRIPTION Gray to Blue Gray, Saturated, Medium to SofE, Sheared Clay - Humid, Much Harder Blue Gray, Moist to Wet, Dense, Clayey Sandstone . END OF BORING 4 i; .* : . I: , =I r 3” ;’ ;: ~~ 2 SLOW COUNT - K - 3" O.D. Sampler, Kelly bar of drill rig drop 1’ per blow. L - 3" O.D. Sampler, 1401b. hammer, 30" drop S - Standard Penetrometer SAMPLE TYPE . U = Undisturbed Drive Sample C =~Chunk Sample B - Bulk 0- Green, Moist to Wet, Medium Stiff, Sandy Mc.dstone 2- 4- 6- a- 0- 2- 4- 6- - 1 1 1 1 1 2 2 - 2 2 2 - 3 3 - 3 3 - 1 -.-. A I 1% ;; I i M L 7 H L Ml P iT L i- Seepage Br~low This Point C'range Brown Layer a- 0- 2- ---------- - -- Light Green Mottled Orange, Saturated, Medium to Stiff, Sandy Claystone -- Clayey Sandstone 4- 6- l .I Buff to Bright Orange Mottled & Gray, Saturated, Medium tc, i.:IrDetISe, Sandstone KEY I BLOW COUNT - K - 3" O.D. Sampler, Kelly bar of drill rig drop- 1’ per blow. L - 3'! O.D. Sampler, 1401b. hammer, 30" drop S - Standard Penetrometer SAMPLE TYPE U - Undisturbed Drive Sample C -,Chunk Sample ~B - Bulk Sample 2- 4- 6’ a- BORING NO, B 32 BORING NO, B 32 130 130 -BORING DIA, -BORING DIA, DESCRIPTION DESCRIPTION ! ;:‘1 1 Buff, Moist, Medium Dense, Sandstone !'I. L:I: I f ;.I: i.r r: f ..I I: .I: I Light Green, Moist to Wet, Medium Dense, Siltstone - 12 - 14 - .E - .a - io - 4 i 1 . g I i 7 H. M BLOW COUNT K - 3" O.D. Sampler, Kelly bar of drill rig drop, 1' pet blow. L * 3'! O.D. Sampler,' 1401b. hammer, 30" drop S = Standard Penetrometer L Sl B 32 (Cont'd) BORING NO. - ELEVATION: - 3 DESCRIPTION . ;:i:i Water Flowing in Sheets Down Side of Hole :f:;jlIrregular Ccntact Dips SE 10' - 15O \ Gray to Blue Gay, Saturated, Soft, Sheared Clay - All Planes Cip into Slope - 15' Doesn't Look Like Slide \ !-:l!i Gray Tan, Saturated, Dense, Massive Sandstone, Some Clay ,..I! END OF BORING -L c !f :c g :: A U = Undisturbed Drive Sample VISTA SANTA FE C =.Chunk Sample B - Bulk Sample - - - - - .- - - - - - - BORING UO, ' 33 156 BORING DIA. DESCRIPTION ff to Orange, Mcist, Medium to Dense, Sandstone S.E.=31 positional Contact 4" of Pulverized Mudstone - Lots cf Red & Yellow Color. Plane Dips 18' N 70' W Brow!-Green Gray Mottled Red 8 Yellow to Light Cray Brown, Moist, Stiff, Very Silty Claystone C 'S':'?; Light Greenish Gray Brow, Moist, Dense, Gritty Clayey Sand <.:,x1 Irregular Contact - Erosional L \Gray Green, Moist, Stiff, Mudstone Gradational Concoidal Fractures Random \ XI\ t WOW COUNT - K = 3" O.D. Sampler, Kelly bar of drill rig drop, 1’ per blow. L - 3" O.D. Sampler, 1401b. hamme.r, 30" drop S = Standard Penetrometer SAMPLE TYPE U = Undisturbed Drive Sample I VISTA SANTA FE C =.Chunk Sample B = Bulk Sample I 6/l/82 PLATE NO. 21 BORING DlA. DESCRIPTION .o - 3 4 4 4 4 \Blue Cray, Moist, IBlue Cray, Moist, - Very Stiff to Hard, Silty Mudstone - Very Stiff to Hard, Silty Mudstone - \' \' Siltstone to Very Sandy Siltstone, Very Massive Siltstone to Very Sandy Siltstone, Very Massive .2 - 14 - \ \ \' \' 16 - I END OF B(fRING BLOW COUNT K * 3" O.D. Sampler, Kelly bar of drill drop 1' 1’ rig drop per blow. * 3'! O.D. Sampler, 1401b. hammer, 30" drop * Standard Penetrometer B 33 (Cont'd) - g - - ._~ - -- - 1 1 - 1 - 1' - 1, 21 - 2, - 2’ 21 - 2, - 31 3: - 31 - 3f I - -- -. A SU BORING NO. B 34 ELEVATION: 148 BORING DIA. 30” DESCRIPTION 2- 3-U i SW , Buff to Oiange Green, Moist, Medium to Dense, Well Graded Clean & Silty Sand I- 6- a- 0- 2- 4- Green Gray to Gray Green, Moist, Medium to Stiff, Clay. Iron Stains Along Fractures 6- a- 0- Fractured But No Clear Slide Zone 2- 4- \ \ \ \ 6- 81 CK D- 2- 4- j- 4 r :L \ :LI ' :H \ \ \ \ \ \ 7 ;c : I IL :L - \ \ & ,. ,I. .,‘..: ‘\‘. ; . ‘2‘ .., \ P Y-l Some Concoidel Fractures Tan Brown, Moist, Dense, Clayey Sandstone Flat Contact Blue Gray, Moist, Stiff to Hard, Sandy Siltstone Flat Contact'& Gray & Light Brown, Moist, Stiff, Claystone 3LOW COUNT - K * 3" O.D. Sampler, Kelly bar of drill rig drop 1’ per blow. L * 3" O.D. Sampler, 1401b. hamer, 30" drop S * Standard Penetrometer SAMPLE TYPE I VISTA SANTA FE U * Undisturbed Drive Sample C =. Chunk Sample B * Bulk Sample PLATE NO. 23 I I I . r $4 i >L/ :H BORING NO, - BORING NO, - B 34 (Cont’d) B 34 (Cont’d) ELEVATION: - BORING DIA, BORING DIA, DESCRIPTION DESCRIPTION O- lue Gray, Moist, Stiff tx Herd, Mudstone to Siltstone t 3ah’ - 5O l/B" to l/4" Wet Gouge - Plane Dips Approximately s 5o" w, Massive 2- ,4 - 6- 3 4 4 '- 4 4 - - - - - - I - - IL - END OF BORING )LOW COUNT - K * 3" O.D. Sampler, Kelly bar of drill rig drop 1’ per blow.- L - 3" O.D. Sampler, 1401b. hammer, 30" drop S * Standard Penetrometer SAMPLE TYPE . U - Undisturbed Drive Sample C -.Chunk Sample B * Bulk Sample VISTA SANTA FE KLS 1 612182 110:75 PLATE NO. 24 2- 4- 6- 8- 0- 2- 4- 6- a- 4- 6- a- D- 2- 4- BORING NO, ' 35 -BORING DIA. DESCRIPTION ,\ Brown to Light Green Brown, Moist, Soft, Clay Laminated Bedding, Flat Planar Contact Dips Out of Slope (NW) 7' - 8' <{ii!' Bedding Same as Above ;$I, 2 " ;l,c. A to 4" Clay Bed - Gouge Looking Put Not Continuous All round Hole - Flat Contact is Irregular and Dips 7' West,Some Punky Clay Be11 Contact But Doesn't Look Like Slide Iron Stained Fractures More Massive Below -.15 c Minor Shear Zone -. Flat BBS ---m---m-- Yellow Green Gray, Moist, Stiff to Hard, Light Weight Siltstone & Claystoce Contact Dips X0 NE - Very #inor Seepage, No Slide Gray, Moist, Hard, Sandy Siltstonc,, Very Massive, V~I Minor Seepage From Golden Sandstone at Bc,ttom 3 la’ Y- ULOW COUNT kc END OF BORING SWFARDSDN ENDINEERIND ASSCICUTES INC. yd Penetrometer - - .- - - -_ - -. - - ,- - - - - , Could Be Healed Shear Zcne, Dip 10' NW Vertical Fractures in Sandstone y at Contact, Undulates Flat Some,Pcssible Shearing locky Fractures racture Zone ripping 25' XW,Orangf Stains Gouge,1/4" to .1/S" Soft Gouge Punky for 3" Above, More Silt Than Clay, dip Approximntcly 18' NW \\ Massive Below rinor seepage [Ll Blue Gray, Moist, Humid, Siltstone !L '\' \\ END OF BORI Km BLOW COUNT - K = 3" O.D. Sampler, Kelly bar of drill rig drops 1' per blow. L = 3'! O.D. Sampler, 1401b. hammer, 30" drop SMEPMDSDN ENWNEERlNG ASSDCIATES. INC. S = Standard Penetrometet SAMPLE TYPE VISTA SANTA FE U = Undisturbed Drive Sample C -. Chunk Sample KLS I b/2/82 B - Bulk Sample 110175 PLATE NO. 26 - .-. .- .- - .-. - - ~- - - - - - BORING NO. B 37 2 Ll 143 ;a BORING DIA, > t 2 z i’ i$ DESCRIPTION 1: 1 Brown, Dry, Soft, Clay, Topsoil \ Light Brown, Moist, Medium Stiff, Clay \ ” .:.: ,:]..;,, Yellow Tan, Moist, Medium Dense, Silty Sand ,.;I< 1: I ,a &rregular - Generally Dips SW loo \\ *\Gray Green, Moist, Medium Stiff, Clay \U Fractured,with Iron Stains oo Surfaces ” of Very Punky Clay - Not Wet or Sticky, Very Minor Plz early Flat --k------B--- ight Brown to Green Gray, Moist to Wet, Medium to Soft lay & Silt ery Sheared - Gouge l/4” Remold Gouge, Well Developed Flare Dip 4’ South ------------- Yellow Brown to Green Light Brown, Moist to Wet, Medium I Very fine gilty Sand to Sandy Silt & Clay Kinor Seepage Seepage-Slight -----P----A Yellow Gray Brown, Moist, Stiff, Mudstone Very E!inor Frac.turcs WI BLOW COUNT - K = 3" O.D. Sampler, Kelly bar of drill rig drop 1' per blow. L - 3" O.D. Sampler, 1401b. hammer, 30" drop S = Standard Penetrometer SAMPLE TYPE - Undisturbed Drive Sample A SANTA FE 1 I 1 . 1: is ki :H - .-- BLOW COUNT - . . K - 3" O.D. Sampler, Kelly bar of drill rig drop 1' per blow. L = 3" O.D. Sampler, 1401b. hammer, 30" drop S = Standard Penetrometer SAMPLE TYPE BORING NO, B 37 -BORING DIA, DESCRIPTION \ Dark Blue Gray to Charcoal, Moist, Stiff, Mudstone Elassive - Some Concoidal Surface L END OF BORING U = Undisturbed Drive Sample C -,Chunk Sample 2- 4- 6- 8- .c- 12- .4- .6- .a- !O- !2- !4- !6- !8- io- ;2- ;4- : p BORING NO, B 38 =i 1 . VI I\ $ -BORlNG DIA, izir z! ELEVATION: 146 j” g DESCRIPTION ? :L Dry to Moist, Soft, Sandy Clay ------v---- Pm- Yellow Red Erown, Moist to Wet, Loose, Very Clayey Sand Brown Gray, Moist tc, Wet, Medium to Stiff, Clay Slide Plane - Flat,Gouge Above,l/0" to l/4" Calicke & Some Major Concoidal Fractures at-34: No Gouge of Slide ,0x- Jtvi& -e Mottled Maroon & Green Brown, Moist, Stiff to Hard, Clay KFX BLOW COUNT - END OF BORING K - 3" O.D. Sampler, Kelly bar of drill rig drop 1’ per blow. 2 k :. 5: -2. 9 L - 3'! O.D. Sampler, 1401b. hammer, 30" drop S - Standard Penetrometer SAMPLE TYPE U - Undisturbed Drive Sample C -.Chunk Sample - .- ~- - -. - - - - - - - - -BORING DIA, DESCRIPTION ark Brown Black, Hl.mld, Medium to Stitt, Clayey Sand uff, Humid, Medium to ECedium Loose, Poorly Graded Clean Sand ight Yellowish Tan, Humid, Medium Stiff, Fine Sandstone S.E.= 36 ellowish Tan Gray, Moist, Medium to Dense, Lightly Cemented ,oorly Graded Clean Sand 1' Contact w/Sandstone Dips 15' West 'assive Sandstcne S.E. = 41 sle Green, Moist tc Wet, Medium to Soft Clay, Very Fracture< I' Soft Zone No Continuous Plane luish Green, Moist, Medium to Hard Clae Contact is irregul; .coks Depositional, Dip Generally NW 10 lore Massive Seepage Wpv I i! ;, , c ;’ 1: a BLOW COUNT 1\01 K - 3" O.D. Sampler, Kelly bar of drill rin I drop 1' per blow. L = 3', 6.D. &mpler, 1401b. hammer, 30" drop S = Standard Penetrometer SAMPLE TYPE - $0 - k2- k4- $6 - M- BORING NO, R 19 fQnt'd) ELEVATION: BORING DIA, DESCRIPTION \ At 40.5' Slide Plane, Dip NW lo', Excellent Well DeveloFed Planes, 2" to 3" Gouge - Hard Below L FND OF BORING -. BLOW COUNT - K = 3" O.D. Sampler, Kelly bar of drill rig drops 1’ per blow. L = 3'? O.D. Sampler, 1401b. hanrmer, 30" drop SNEPMOBON ENGINEERING ASBOCLNES. INC. - ,- -~ - -~ - - - - - - - - - - - Fractun Dip WSW 5' at 7' Occasional Mudstore Beds Dip WSW,l/Z - 2" Thick 25' WSW Overlying Near Horizontal Very Fractured Mudstore, Black Seams - No Organic Odor Medium to Dense, Massive Sandy Mudstone, Fractured Seepage at 30.5' - Winor Wore Massi.ve BLOW COUNT K - 3" O.D. Sampler, drop 1' per blow. Kelly bar of drrll rig = 3" O.D. Sampler, 1401b. hammer, 30" drop 4 :. , t :, i: 1. 2 4- 6- 8- .o - ,2- ,4 - ,6 - I - I@ - ‘2 - ,4 - ,6 - 3 - O- 2- 4- 1 BORING NO, B 41 l/4” to l/2” Sheared Clay - Slide Plane - Flat Some Calich Cornflake Texture Massive Below ---mm- -- --a w Tan Brown to Green Gray to Brown, Moist, Medium to , Very Massive Mudstone ,CTT/17‘(1’ KEY END OF BORING BLOW COUNT - K - 3" 0.D: Samp+, Kelly bar of drill rig 4- 6- 8- o- 6- 2- 4- 6- 0- 0- 2- 4- 6- SI BORIiiG NO, R BORING DIA. DESCRIPTION rown to Green Brown, Moist, Soft, Clay ,reen to Gray to Light Brown, Moist, Medium to Hard, Very 'ractured Mudstone, No Slide 'airly Massive ellowish Brown to Brown Green Gray Mottled Maroon, Moist, ard to Medium Mudstone egin Maroon Mottling arge Blocky Fractures ellowish Brown to Brown, Hard, Very Massive ery Hard YW , .-I BLOW COUNT - END OF BORING K - 3" O.D. Sampler, Kelly bar of drill rig drop, 1' per blow. I a i; ;’ 1: I L - 3'! O.D. Sampler, 1401b. hammer, 30" drop SNRMPSON ENGlNWlNG ASSOClAlEB. INC. S - Standard Penetrometer SAMPLE TYPE VISTA SANTA FE U = Undisturbed Drive Sample C -.Chunk Sample B - Bulk Sample KLS 110175 1 613102 PLATE NO. 34 - 2- 4- eared Surface 1” Gouge - Some Mineralization, oft, Sandier - Gradational 6- 8- O- 2- 4- Hard, Very Fractured Mudstone 6- S- ‘1! - - - -~ - -1 1 - 1 - 1 1 -. 2 - 2 - 2 2 2 -3 3 - 3 - 3’ 1 .- - -- . .._ .- More Massive o- 2- 4- 6- 8- o- 2- 4- 6- _-_ BLOW COUNT - K = 3” 0.1). Sampler, Kelly bar of drill rig drops 1’ per blow. L = 3” O.D. Sampler, 1401b. hammer, 30” drop S = Standard Penetrometer SAMPLE TYPE U = Undisturbed Drive Sample C =~Chunk Sample B = Bulk Sample 38- $0- \2- i4- 16 - i8 - io - A I I . ,:: $3 L c :H :L - BLOW COyT K = 3" O.D. Sampler, Kelly bar of drill rig drop~l' pe - - I L = 3" O.D. Sa-, mpler, 1401b. hammer, 30" drop c - c-^--l---l lB^. SU B 43 (Cont'd) BORING DIA. 30” DESCRIPTION I. .I ,_ Maroon to Green Brown Mottled, Moist to Saturated, Medium to Hard, Clay Blue Green & Some Mottled Maroon, Moist, Hard, Very Massive, Blocky, Clay END OF BORING i! f, , t i’ 1; 3 - - -. - - - -, - - - .- - - -. - - - - 2- 4- 6- 8- o- 2- 4- 6- 8- ,o- 2- 4- 6- 8- o- 2- 4- 6- __ BORING NO. B 44 DESCRIPTION Brown Buff to Yellow Brown, Moist, Medium Dense, Clayey & Clay Blue Green to Pale Green to Dark Pale Green, Humid to Moist Medium Stiff, Clay Contact Dips Steeply North 45' Extremely Fractured Mudstone Light Grayish Tan to Mottled Blue Green to Buff Maroon to Pale Green, Moist, Soft to Medium Hard, Clay.(Slip Plane Dip -15' 1" Gouge, Very Sheared 6' Below) WNW Fractured More Massive & Blocky Very Massive B Hard with Fractures Very Sandy Mudstone - No Fractures Dark Green to Yellow Tan, Humid, Medium Stiff, Silty Sand 8 Clay, Grades into Silty Sand Minor Seepage Dark Greenish Brown, Humid to Moist, Medium Stiff, Clay, Very Massive Sandy Mudstone, Gradational with Sand Lens Dark Green to Maroon Mottled, Moist to Wet, Medium to Hard Clay, Mudstone, Some Minor Seepage I\ pinor Seepage at 37’ KEY _-_ BLOW COUNT - K = 3" O.D. Sampler, Kelly bar of drill rig drop, 1' per blow. L = 3'! O.D. Sampler, 1401b. harmner, 30" drop S = Standard Penetrometer io - Brownish Green to Maroon Mottled,oWet to Saturated,@34.5' . Fracture with Some Gouge,Dip N 45 , Sheared Red Brown to Mottled Green Red i2 - i4 - Light Brown to Maroon Mottled, Moist, Medium Stiff, Clay Seepage from 37 to 54’ i6 - A j iL- :H :L - Blue Gray to Maroon Mottled, Moist, Medium to Hard, Massive Sandy Mudstone i8 - jO- i2 - i4 - END OF BORING BLOW COUNT - K - 3" O.D. Sampler, Kelly bar of drill rig drops 1’ per blow. L - 3" O.D. Sampler, 1401b. hanrmer, 30" drop 8 - Standard Penetrometer SAMPLE TYPE . U - Undisturbed Drive Sample C -.Chunk Sample B = Bulk Sample su BORING NO. - B 44 (Cont'd) BORING DIA, DESCRIPTION 2- 4- 6- 8- 0- 2- 4- 6- 8- 0- 2- - - ._ -1 1 - 1 1 1 - 2 2 - 2 2 - 2 - 3( 3; 31 3t B I -- 4- -I CK 6- 8- I- ,- i- i- I I, \I KEY ILOW COUNT - K - 3" O.D. Sampler, Kelly bar of drill drop 1' per blow. L - 3" O.D. Sampler, 1401b. hammer, 30" S - Standard Penetrometer iAMPLE TYPE U - Undisturbed Drive Sample C -.Chunk Sample B - Bulk Sample to Moist, Medium to t, Very Sheared Mudstone, Some Possible Shearing with Thi wn & Yellow Beds, Bedding Horizontal Yellowish Tan Brown with Bright Yellow & Orange, Moist, Stiff, Clay, Much Less Fractured,Bedding 13' SSE, Gypsum Green Gray Mottled Maroon to Blue Gray with Maroon Mottling Moist, Stiff to Hard, Clay. rig I drop SliEPARDSONENWNEERlNG AssoclATEs. INC. VISTA SANTA FE 110175 I r~,*, [ PtA?E NO. - - - - - - - - - - - - - .- ,~. .- 10 - r2- ,4- 16 - BLOW COT KEY - I -- , K - 3" O.D. Sampler, Kelly bar of drill rig droD , t ..a- I.,,.... p.& ““F. L - 3" b.D. Sampler, 1401b. hammer, 30" drop S - Standard Penetrometer SAMPLE TYPE BORING NO, B45 (Cont'd) l-3 ELEVATION: p -BORING DlA, DESCRIPTION \ END OF BORING SHEPARDSDN ENGINEERING ASSGCIATES. INC. VISTA SANTA FE U - Undisturbed Drive Sample C -~Chunk Sample B - Bulk Sample 2- 4- 6- 8- LO- .2- .4- .6 - .0 - 10 - 12 - :4- 6- a- o- 2- SI BORING NO, B DESCRIPTION Blueish Brown, Humid, Medium to Soft to Medium Very Fractured De1 Mar Sandy Clay More Massive Pale Greenish Gray to Buff Mottled, Moist, Medium Stiff Cla: AT 5%'& west 5 Possible Slip Plane l", Very Sheared, Dip Generally \ More Massive with Depth Some Minor Gypsum Deposits \ Yellow & Brown, Moist, Medium to Dense Clay, More Gypsum, Fractured 8 Flakey Yellow Veins in Fractures - Undulated Veil .( : Yellow to Buff, Moist to Wet, Medium Stiff, Poorly Graded ;I; Fine to Medium Sand, Clean - Gradational Contact Dip N. , . I ::, 'sl9.5 Basal Slide Plane,Dip 7' West,f-2" Gouge Very Fractured -.Below Light Gray to Dark Grayish Brown to Dark Gray Brown, Wet, Medium Stiff Clay with Some Mottled Red Color, Very Sheared & Very Fractured, Random Diping Veins \ Dark Bluish to Greenish Gray & Mottled Red, Moist to Wet, Hard, Sandy Massive Mudstone. with Some Fractures _-_ BLOW COUNT - END OF BORING K - 3" O.D. Sampler, Kelly bar of drill rig drop 1' per blow. L - 3" O.D. Sampler, 1401b. hanrmer, 30" drop S = Standard Penetrometer SAMPLE TYPE U = Undisturbed Drive Sample C =~Chunk Sample B - Bulk Sample - 2- 4- 6- 0- 0- 2- 4- 6- 0- 0- 2- 1 CK 4- 6- a- o- 2- 4- BORING NO, R LEVATION: 166 BORING DIA. DESCRIPTION Very Dark Brown-Black, to Very Dark Brown-Olive to Olive Brown, Humid to Wet, Medium to Soft, Clay, Topsoil, Sandy Topsoil - Colluvium Olive to Dark Brown Black, Wet, Soft, Clay, Sheared, Soft, Mudstone, Very Sheared & Remolded 7' to 11.5 L/ Dark Olive; Wet, Medium Stiff, Clay, Very Soft & Sheared H 6-17', with Slikensides, Very Fractured with Slikensides, Very Fractured \ n Mottled Dark Green & Buff I\ \ L- Dark Green & Mottled Buff to Light Brown, Moist, Medium to H Hard, Clay, Some Seepage at 3J', Massive & Lightly Fractured Some Caving Above Seepage at 20', 3-4 GHP ted, Soft Clay, Fgactured More p Plane,Dips S 30-4 with 1'52*l Very Light Gray to Buff to Light Gray Green, Moist, Medium Stiff, C:ay~ y Dark Bluish Gray, Moist, Medium to Hard, Clay, with Some Seepage BLOW COUNT = END OF BoR1NG K = 3" O.D. Sampler, Kelly bar of drill rig drops 1' per blow. L = 3" O.D. Sampler, 1401b. hanrmer, 30" drop S = Standard Penetrometer SAMPLE TYPE ' u = Undisturbed Drive Sample C =. Chunk Sample B = Bulk Sample - .- .- - - - .- .- - - - - - - - - 2- 4- 6- 8- .0- .2- .4- .6- .8 - !O - !2 - !4- !6 - !8- IO- IZ- 14- l6- A . iti Er: H L - L- H BORING NO, B 48 DESCRIPTION . Dark Brown to Olive, Humid to Wet, Very Soft Clay Dark Olive, Moist, Medium Stiff Clay, Very Fractured Mudstone with Iron Stains Y &en to Mottled Rust Green Gray, Moist, Soft to Hard Clay Fractured & Slikensided, Fairly Massive \ Mottled Maroon to Green Brown, More Massive, Still Fractured Reddish Green to Mottled Maroon, Massive Brown Green & Mottled Maroon, Some Continuous Fractures with Iron Stains but not Slide Planes Pale Green Gray & Mottled Reddish Maroon, Medium to Hard Clay END OF BORING -. - - - - - -- - - - - -. ~-. & I I vi I !3 b 1P - X - :Ll :H Yi7 :H - :L :L/ xl - DESCRIPTION Brown, Wet, Stiff, Clay . ,. 't Buff to Orange, Wet, Mediuz Stiff, Poorly Graded Clean Sand Non Plan r Contact Dips 7 N Stiff, Clay, Cornflake Texture row" Streaked Yellow, Very Wet, Soft to Medium Clay Very Thin Lamina‘ , S me Dip as Above,Some Gypsum Green Gray, Wet to Saturated, Soft to Medium Clay, Very Fractured w/ Sulfur in Fractures Gray Green to Green Brown to Brown Gray with Maroon Mottling, Moist, Medium to Stiff, Clay, -At 111, Fairly Well Developed Plane Dips 25' E. k" Gouge in Places. Definite Shean, Probable Base of Slide. At 14' Another Gouge Zone but Not Nearly Well Developed as the One at 11'. Not Continuous. Fractured Massive Some Undulating Concoidal Fractures with Yellow Stains -a BLOW COUNT - K = 3" O.D. Sampler, Kelly,bar of drill rig drops 1' per blow. L = 3'! O.D. Sampler, 1401b. hammer, 30" drop dard Penetrometer .- ,~- - - . . . - - -_ -. - - - - ._ - B 49 (Cont’d) BORING DIA. DESCRIPTION Brown Gray Streaked Golden, Moist, Stiff to Very Hard, \ Clay - END OF BOING -s BLOW COD?iT - K = 3" O.D. Sampler, Kelly bar of drill rig ,drop 1’ per blow. I L - 3" O.D. Sampler, 1401b. hanmer, 30" drop SNUARDSON ENGINEERING AssoaAlEs. INC. dqd Penetrometer 4- 6- a- LO- 12- L4- L6- L8- !O- !2- !4- !6- !a- IO- 14- l6- A . tn 3 F L r ,H F L r - BLOW COYT KEY END OF BORING - K = 3" O.D. Sampler, Kelly bar of drill rig drop 1' per blow. fj-- L - 3" O.D. Sampler, 1401b. hammer, 30" drop SNUARDSDN EN- AssDclATEs. INC. S - Standard Penetrometer SAMPLE TYPE VISTA SANTA FE SI 3~ BORING NO, % 0 ELEVATION: 17’ -BORING DIA, 30" 3 DESCRIPTION T$ e- Dark Brown Black, Humid, Medium to Loose, Clayey Sand & Clay LA.\ :- Dark Green Blueto Mottled Green Maroon to Green Brown, Humid to Moist, Very Fractured Mudstone Fractured Slightly More Massive At 14' Secondary Plane Dips 35' N, Punky q?; \A Yellow Green, Moist, Medium Stiff, Clayey Sand & Clay h;. ‘. ‘. :.i,; Mottled Pale Brown to Red, Wet to Saturated, Moist to Humid, At 20' Medium Hard, Massive Mudstone Some Seepage from Fracture Green Brown & Mottled Red, Medium to Hard, More Massive @29' Prominent Fracture Dips E at 45', Very Sheared, Fracture with Little Gouges l/4" of Punky Non Platic Gouge, Hard above & below. Parallel Fracature 1' Below. =I r 3” ;- :: g 2 U = Undisturbed Drive Sample C -.Chunk Sample B - Bulk Sample - 2- 4- 6- 8- LO- LZ- L4- 16- L8- LO- !2- !4- !67 !8- r p a-4 su BORING NO, B s . g 1 ELEVATION: - il DESCRIPTION -I I SC- r.k'J Dark Brown Black, Humid to Moist, Medium to Loose. Clavev CL '< '1 Sand h Clay, Topsoil Colluvium, . _ Light Green to Pale Blue Green, Humid to Moist, Medium to Very Fractured Clayey Sand & Clay SP - :: : Pale Green to Buff to Light Reddish Gray to Mottled Purple -. * :.. Green Maroon, Fine to Medium Sand w/Clay Binder i:' ..* ; is Massive I I . ::* . l - .:* . . ! I Medium Sand - Lightly Cemented, Concretion Blue Green & Bu Clean Fine Silty Sand with Clay Binder, Lightly Cemented racture, Little Gouge, Undulated Contact Generally Dips 5's. Very Silty in Some Parts O.D. Sampler, Kelly bar of drill rig drop 11 per blow. L - 3'! O.D. Sampler, 1401b. hammer, 30" drop - . - - - - - - -- - - - - - - su BORING NO, B 52 LEVATION: I” BORING DIA, DESCRIPTION Yellow Tan, Moist, Medium Dense, Sandy Mudstone .‘...\ ‘. ..i” :L- Green Brown 8 Some Mottled Maroon, Moist, Medium Stiff, Clay :%I Fractured Mudstone Some Mudstone Beds in Sandstone Some Mudstone Beds in Sandstone el3' Some Moderately Sheared Mudstone Underlying the Sandstone el3' Some Moderately Sheared Mudstone Underlying the Sandstone non Real Gouge But is Sheared,Dip W loo non Real Gouge But is Sheared,Dip W loo No Slide No Slide More Massive More Massive E .!<..-J,, Brown Green, Moist Medium to Dense, Clayey Sandstone, :'-r' Massive ;. .\-‘ \ L- Green & Mottled Maroon to Red & Maroon Mottled Brown Gray, H Moist to Wet, Medium to Hard, Clay, Wet Spot, Some Fractures, Hard Massive Mudstone to 36' END OF BORING YW I A ;. , I ;’ 1; I .-- BLOW COUNT - K = 3" O.D. Sampler, drop. 1’ per blow. Kelly bar of drill rig L = 3" O.D. Sampler, 140lb. hammer, 30" drop S = Standard Penetrometer SAMPLE TYPE U - Undisl c =. 6- a- LO- .2- 14- 16- .a- !O- !2- !4- !6- !a- IO- 12- i4>, Sandy Mudstone Less Fractured Random Slicked Fractures Moist to Wet, Stiff to Hard, ----v-m-- w -- Moist, Hard, Mudstone is a Sheared Clay Seam Much Softer Than Clay- & Below. Doesn't Look Well Enougg Dgveloped for or Remolded Di& -3 NE. -m- - --- Very Hard, Mudstone, Massive with Some Fracturing KEY END OF BORING BLOW COUNT - K = 3" O.D. Sampler, Kelly bar of drill rig drop 1' per blow. L a 3" O.D. Sampler, 1401b. hammer, 30" drop S = Standard Penetrometer SAMPLE TYPE U = Undisturbed Drive Sample C -,Chunk Sample 4- 6- a- .o- 2- 4- 6- a- o- 2- 4- 6- a- 0- 2- 4- 6- BORING NO, B 54 BORING DIAa Plane Plas l/Z" Gouge & Plastic uish Green to Light Green to Light Tan Green, Moist, Medium Hard, Sandy Massive Clayey Sand & Clay. .5' Slide Plane, Good Planar Slip, Dips South 5' W ,I#" uge - Very Distinct Laminated Buff, Brown 8 Gray, Moist to Wet, Medium to Dense, Clayey Sand & Clay, Very Sandy & Clayey Laminted Beds F- I:: ::: Yellow to Yellow Tan to Dark Brown & Gray, Moist to Wet, +,,: ;.,: Medium to Dense, Poorly Graded Clean Sand , : Yellow to Yellow Tan, Wet to Saturated, Medium Dense, Poorly :a I . I . @-aded Clean Sand KEY I BLOW COUNT - K = 3" O.D. Sampler, Kelly bar of drill rig drop I' per blow. L = 3" O.D. Sampler, 140Lb. hammer, 30" drop SNECARDSON ENWNEERlwG AsscclAlEs. INC. S - Standard Penetrometer SAMPLE TYPE VISTA SANTA FE IJ = Undisturbed Drive Sample C =,Chunk Sample CB B = Bulk Sample I 619182 110175 1 PLATE NO. 50 - - .- .,- - - - - - - - - - - - - I ! 8:: i; 4 i :H :L: :H Sl BORING NO, B 54 (Cont'd) ELEVATION: -BORING DIA, DESCRJPTION \ at 37' Seepage - H20 Flowing Freely into Hole Gray Mottled Maroon, Saturated, Veiy Fractured Clay \ \ I \ Green Blue, Wet to Saturated, Medium.Stiff Clav ore Massive with Depth I Slide Observed 37 to 50' 1 END OF BORING \ Massive to 50' BLOW COUNT K = 3" O.D. Sampler, Kelly bar of drill rig drop 1’ per blow. L = 3" O.D. Sampler, 1401b. hammer, 30" drop S = Standard Penetrometer SAMPLE TYPE II = Undisturbed Drive Sample VISTA SANTA F - -. -. - - - - .- - - - - - - .- - A 1: i; I L L r H L L- H DESCRIPTION Dark Olive Brown to Dark Olive, Humid to Wet, Medium to Soft Clay, Topsoil - Colluvium Weathered vudstone .UndulatinR Contact Generally Dips 12 S \ \ Pale Green Gray & Mottled Buff to Pale Green, Very Fractured Clay Brown to Green with Some Mottled Maroon, Wet, to Green with Some Mottled Maroon, Wet, Possible Normal Fault,Strike W, Dip & Possible Normal Fault,Strike W, Dip & Several Major Fractures Parallel to Above Several Major Fractures Parallel to Above Begin Very Minor Seepage Begin Very Minor Seepage Sandier, More Massive, Still Fractured I I I\ r KEY BLOW COUNT - END OF BORING K - 3" O.D. Sampler, Kelly bar of drill rig drop 1' per blow. L = 3" O.D. Sampler, 1401b. hammer, 30" drop S = Standard Penetrometer SAMPLE TYPE u = Undisturbed Drive Sample C = Chunk Sample B = Bulk Sample Hard, Massive Fractures 40' S r 3+ . . i; if 1 SE SHEPARDSGN ENGINEERING A.SSWLA~. INC. BORING NO, B 180 BORING DIA. SURF DESCRIPTION I s Orange & Tan, Wet, Soft to Loose, Clayey Sand . Green & Gray, Wet, Soft, Clayey Sand & Clay, Mix:ure of Fine Sand & Lenses of Clay 6- aJ CK Avery Well Developed Slide Zone at 7%'. 1" of Plastic Remoldec Clay Dips B" Westerly Light Gray Streaked Orange, Wet, Medium to Soft to Medium, Clay 9 Fairly Soft For 3' Below Slide 4- Massive Mudstone 6- a- Green Mottled Mdroon & Gold, Moist Clay, Very Few Fractures o- 2- Light Green Brown Mottled Maroon, Moist, Stiff to Hard, Massive Mudstone with a Few Fracture Zones 4- 6- a- 0- 2- 4- Varigated Maroon & Green Gray, Moist, Stiff, CLay 6- ;r >” 1 ;’ 1: - R&a& BLOW COUNT - K * 3" O.D. Sampler, Kelly bar of drill rin I drop 1’ per blow. - I PARDSON ENGINEERING ASSOCIATES. INC. L = 3" b.D. Sampler, 1401b. hasnner, 30" drop S = Standard Penetrometer SAMPLE TYPE LI = Undisturbed Drive Sample C = Chunk Sample B = Bulk Sample - .- -. - -_ - - - - - - - - .- .- - BLOW COUNT K = 3" O.D. Sampler, Kelly bar of drill rig drop 1’ per blow. L = 3" O.D. Sampler, 1401b. hammer, 30" drop SIIEPARDSON ENGINEERING ASSOCIATES. INC. S = Standayd Penetrometer SAMPLE TYPE Sl. B 56 (Cont'd) I- ELEVATION: -BORING DIA, DESCRIPTION Blue Gray, Moist, Very hard, Claystone A END OF BORING IJ = Undisturbed Drive Sample C = Chunk Sample B = Bulk Sample KLS 110175 I 619182 PLATE NO. 54 !!2 i 2 -BORING DIA, DESCRIPTION i a Green Brown, Moist, Soft, Clay, Topsoil d . \ Buff & Golden, Moist to Wet, Medium Dense, Poorly Graded Clean & Silty Sand 6- a- 0- l/S" Wet Sheared Clay Along Planar Contact , Dip W 8' Light Green Gray, Moist, Medium Stiff, Clay 2- 4- Gray, Moist to Wet, Medium to Coarse Sandstone 6- Wet Sheared Sticky Green & Gold Clay Remolded Well Developed Plane,Slide Plane Dips 8' WSW Dark Gray Green Mottled Maroon & Gold, Moist, Stiff to Hard Mudstone, Massive Fractured 4- 6- 8- 3- 2- lark Blue Gray, Moist, 7- Hard to Very Hard, Mudstone 4assive PRY _.-- I SLOW COUNT - K s 3” O.D. Sampler, Kelly bar of drill rig drop I’ per blow. L - 3” O.D. Sampler, 1401b. hammer, 30” drop S = Standard Penetrometer EERING ASSOCIATES. INC. - ..- - - - - - - - - - - - - - - ,,- -uu: I . ,: ii3 ;c- _’ :L ;; i ic ,; :L ;P : sl. BORING NO. B 58 DESCRIPTION Dark Brown Olive to Brown, Humid to Moist, Medium Dense, * Clayey Sand & Clay Green & Buff to Brown, Moist, Soft Clayey Sand, Very Sheared & Jumbled Dark Gray & Buff, Moist, Medium Stiff, Clay, Fractured Mudstone, Grades into Poorly Graded Clean Sand . . . . . . ;: Light Tan, Moist to Wet, Medium to Loose, Poorly Graded i: Clean Sand, Medium to Fine Massive Sandstone row" - Yellow, Saturated, ry Sheared Below Plane. Medium to Hard, Clay More Massive with Depth. to Hard, Clay, - Seepage at 22 - 24' ith Minor Seepage KEY BLOW COUNT - END OF BORING K = 3" O.D. Sampler, Kelly bar of drill rig drop 1' per blow. L = 3" O.D. Sampler, 1401b. hammer, 30" drop SHEPARDSON ENGINEERING &SoC,A,ES. INC. S = Standard Penetrometer bed Drive Sample - .- - - -- - - - -- - - - .- - BORING DIA, DESCRIPTION \I (“y Dark Brown Olive to Olive Brown, Humid to Wet, Soft, Clayey $'; Sand & Clay, Topsoil ‘< ;,!i,;dWhitish Tan, Moist, Medium to Loose, Poorly Graded Clean & :.:‘$ Clayey Sand i:: Pinkish Tan, Moist, Medium to Dense, Poorly Graded Clean San .': . . - * . I: i White, Moist, Medium Dense, Poorly Graded Clean Sand ,' I ::: 'I, I '; : ' 8' ." ::i . * * I I' :,a I.1 -9. " I :: I I; : Pinkish Tan, Wet to Saturated Buff to Rust, Wet to Saturated, Very Loose, Clayey Sand & Jumbled Sandstone, Mudstone & Dark Loose Silty Sand Gray, Wet to Saturated, Soft, Clay, Seepage B!ue Green, Moist to Wet, Medium to Hard, Clay, Slip,Pla;;, *Very Sheared & Remolded, Laminated Zone 2'16" Thick with l-2" Gouge - W / Well Developed Dip West Generally 5-10' Fractured Massive Claystone \U Black Gray, Moist, Hard, Clay, With Some Gypsum Beds s[.::< Gray to Buff, Moist, Dense, Clayey Sand . ,t ,.,., ;.-\\ White, Moist, Medium to Dense, Poorly Graded Clean Sand ,,\‘. Mottled Color Medium Sand -Slightly Cemented, Clean -;>;: !;: ' _--_ BLOW COUNT - K = 3" O.D. Sampler, Kelly bar of drill rig drop 1' per blow. L = 3'! O.D. Sampler, 1401b. hannner, 30" drop S = Standard Penetrometer - 3 4 4 4 4 - 4 - 5 - - - - - .- - A .o - .2 - .4 - ,6 - 8 - o- =I I 1% ;; I i C - E :%I/ :H - - SU SU BORING NO, B 59 (Cont'd) B 59 (Cont'd) ELEVATION: - BORING DIA. BORING DIA. DESCRIPTION ;I Red to Tan, Moist* Dense, Clayey Sand, ; ; Bedding Dips S 10 ; Seepage 25gpm in Clean Sand ; : : I ' Standing Water at 43' After 2 Hours . . Dark Blue Gray Brown, Saturated, Soft, CLay \ Dark Blue Gray, Wet to Saturated, Medium to Soft, to Medium Hard, Clay, Slip Plane - Very Plastic, Dips WNN at 5' \ '1" Plastic GougesVery Sheared & remolded Hard Massive END OF BORING BLOW COUNT _.-- - K - 3" O.D. Sampler, Kelly bar of drill rig drop 1' per blow. L = 3" O.D. Sampler, 1401b. hammer, 30" drop S = Standard Penetrometer - - .~ - - - - - - .- -- - - - - - 1 ! ! - rz Ii3 ! i iC- :L Yr :H. z7 iM - :L- :H - L - Llc 7 ‘. L I .A. \ \ 7 : ,I ‘.1 ;; A \ \ \ \ \ \ \ \ \ \ \ 1 BORING NO, B 6o DESCRIPTION Gxi Very Dark Brown to Dark Brown Olive, Humid, Medium to Soft, ‘,,T Clayey Sand & Clay ,', : , Brown Green Mottled Maroon & Gold, Humid to Moist, Medium, Very Fractured Mudstone 1 :,); Yellowish Tan, Humid to Moist, Medium to Dense, Clayey Sand (I: to Sand ,:I. ':. 31‘ Brown Green 8 Mottled Maroon to Brown Mottled Maroon to Pale Olive, Moist, Hard, Fractured Mudstone Massive with Random Fracture More Massive \ \ Puulish Gray to Reddish Purple, Moist, Hard, Sandy Claystone Very Massive, no Fractures at all. , BLOW CODNT ..I I - K - 3" O.D. Sampler, Kelly bar of drill rig drop 1' per blow. SE SHEPARDSDN ENGINEERING ASSGC,ATES. INC. - - - - - - - - - - - - - - - .- BLOW COUNT -.-- - K = 3" O.D. Sampler, Kelly bar of drill rig I B 60 (Cont'd) BORING DIA. DESCRIPTION \ Dark Gray Brown, Moist, Hard to Very Hard, Claystone * 1 END OF BORING drop 1' per-blo;. L = 3" O.D. Sampler, 1401b. hammer, 30" drop S = Standard Penetrometer SAMPLE TYPE U = Undisturbed Drive Sample C = Chunk Sample B = Bulk Sample 110175 PLATE NO. 60 1 1 1 1 1 2 2 2 2 2 - 3 3 3 - 3 6 0 ,2 ,4 ,6 ,a 10 12 14 16 18 '0 '2 ;4 '6 ui- 1 P e g i 4 ? lLE :a C S C C C C C C C C =I I / ’ tn’ Iv1 i2 r r 77 :H !i7 :H - :H :L :L/ :H - SI BORING NO, % ELEVATION: 172 -BORING DIA, 30" DESCRIPTION Gray Brown, Humid, Medium Stiff, Clay, Topsoil Golden Tan, Moist, Medium Dense, Sandstone .Sheared & Gouged at Contact, Soft Clay But no Well Developed Gray Green Streaked Orange, Wet, Medium Stiff, Fractured Mudstone Light Green Gray, Moist, Stiff, Massive Mudstone Gray Green Mottled Rust to Light Green to Dark Gray Green Mottled Maroon, Moist, Hard, Massive Mudstone with Minor Fractures Very Sandy Claystone 1 Massive Claystone END OF BORING KEY I BLOW COUNT - K = 3" O.D. Sampler, Kelly bar of drill rig drop 1’ per blow. L = 3" O.D. Sampler, 1401b. hammer. 30" drop SHEPARDSON ENGINEERING ASOCIA,‘ES. INC. S = Standard Penetrometer SAMPLE TYPE VISTA SANTA FE U = Undisturbed Drive Sample C = Chunk Sample KLS 1 6/11/82 B = Bulk Sample 110175 i PLATE NO. h, - - .~- - - - - - - - - - - . 2- 4- 6- 8- o- 2- 4- 6- a- O- 2- 4- 6- 6- o- 2- 34- 36- Sl BORING NO, R ELEVATION: Ia2 -BORING DIA, 30" i” a 0 DESCRIPTION I :L/ Brown, Humid, Soft, Clay, Topsoil :H \ r\ '\ Green to Light Green Gray, Moist, Medium to Hard, Sandy :H Mudstone At 6' Horizontal Caliche & Punky Orange Clay Band,Doesn't \' Look Like Slide, Massive Below l-d i ;M/ '::$$ Buff & Orange, Moist, Medium to Dense, Sandstone Dark Gray Green, Moist, Stiff to Hard, Fractured Mudstone Brown & Green Mottled Maroon to Brown Gray Green Mottled, Stiff, Massive Mudstone Light Green Gray, Moist, Siltstone haal BLOW COUNT - END OF BORIN K - 3" O.D. Sampler, Kelly bar of drill rig drop 1’ per blow. L = 3" O.D. Sampler, 1401b. hammer, 30" drop S * Standard Penetrometer SAMPLE TYPE bed Drive Sample VISTA SANTA FE E z F 32 g 33 z cl 38- i0- i2- i4- BORING NO, B 62 (Cont'd) ELEVATION: BORING DIA. DESCRIPTION \ Green Brown, Moist, Stiff, Mudstone END OF BORING _.-- BLOW COUNT - K - 3" O.D. Sampler, Kelly bar of drill rig drop 1’ per blov. L = 3" O.D. Sampler, 1401b. hammer, 30" drop S = Standard Penetrometer L L L L I- L L L L L L L L I Very Dark Brown, Humid to Moist, Medium to Loose. Clavev Sand 8 Clay Very Dark Brow to Olive, Moist to Wet, 111.11 . Medium to Loose, Clayey Sand & Clay, co11uvtum Dark Olive, Moist to Wet, Medium Dense, Silty Clayey Sand, Weathered De1 Mar, Very Fractured. Buff to Ltght Tan, Humid to Uoist, Medium Dense, Poorly Graded Clean Sand, De1 Mar BOTTOM OF TRENCH T2 Very Dark Brown Black, Humid to Moist, Medium to Loose, Clayey Sand, Weathered De1 Mar, Topsoil Buff, Hoist, Medium Dense, Clayey Sand BOTTOM OF TRENCH %.Y D = In-Place Density (pcf) M = Natural Moisture Content (%) n 10.1 SHEPARDSON ENGINEERING ASWCIATJSS. Inc. VISTA SANTA FE TRENCH LOGS BY DATE CB 5125182 .Kmiw 110175 PLATE NO. 64 1 s 1 1 1 L L I L L L 1 1 1. L T3 Verv Dark Brown, Humid, Medium to Loose, Clayey Sand 6 Ciay, Topsoil ----mm- -- Very Dark Brown Olive to Dark Olive Brown, Moist, Medium to Loose, Collutium Bluish Green, Humid to Moist, Medium to Loose. Clay, Fractured, De1 Mar D n . 105.1 12.4 BOTTOM OF TRENCH T4 Very Dark Olive Brown to Dark Olive Brown, Humid to Moist, Medium to Loose to Medium Clayey Sand & Clay. Topsoil, Colluvium Dark Olive, Moist, Medium,Colluvium Buff to Olive Buff, Moist to Wet, Medium Dense, Blue Green, Moist to Wet, Clay, Fractured De1 Mar BOTTOM OF TRENCH . L VISTA'SANTA FE SHEPARDSON ENGINEERING ASSGCIATES. Inc. BY DATE CB TRENCH LOGS 5/25/02 1 XBNO. 110175 PLATE NO. 65 T5 Clayey Sand & Clay. Colluvim . Medium Dense, Clayey Sand, Colluvium BOTTOM OF TRENCH Clayey Sand & Clay, Topsoil Dark Gray Buff, Hoist, Medium to Dense Torrey Sandstone- Massive BOTTOM OF TRENCH L L ,.,,.. <: .,.’ SC 2 ..i. ., ; SC- I.\.-:. L E 4 L T7 Dark Olive Brown, Humld, Medium to Loose, Clayey Sand, Topsoil Olive Gay, Humid to Moist, Medium to Loose, 'Clayey Sand & Clay, Weathered De1 Mar Light Brown Buff to Gray. Moist, Medium to Dense Clay, De1 Mar BOTTOM OF TRENCH I VISTA SANTA FE SHEPARDGON ENGINEERING ASSQCUWES, Inc. BY CB DATE 5/25/02 TRENCH LOGS .ceNo 110175 PLATE NO. 66 “II) ar Formation Ver 1 1 1 L L L 1~ L L L L BOTTOM OF TRENCH T9 Dark Brown Olive to Olive Brown, Humid to Hoist, Medium to Loose, Clayey Sand & Clay Topsoil and Colluvium Mar, Weathered BOTTOM OF TRENCH T 10 Clayey Sand, Topsoil De1 Mar, Fractured. BOTTOM OF TRENCH 102.7 14.7 VISTA SANTA FE I SHEPARDSGN ENGINEERING ASSGCIATES. Inc. ( - BY DATE CB JP" I~clr!C 5/25/02 I TREL,.. ..v.,y r"" 110175 I PLATE NO. 67 1 1 1 I 1. 1 T 11 D n Dark Olive Broyn to Olive Brown, Moist to Wet, Medium Dense, Clayey Sand b Clay . Colluvium, Fractured 1 I Red to Gray, Moist, Medium to Stiff, Clay .L BOTTOM OF TRENCH 1 1 L 1 1 1 I: L T 12 ::;;:.y; i I SC ",\C Very Dark Brown-Black, Humid to Moist, Medium A; .:.?, :. to Loose, Clayey Sand, Topsoil \ 2 ycg sc- Light Olive Tan, Moist, Medium Dense, Clayey Sand & Slay, Colluvium 4 “.\ 01 2 :, Olive to Bluish Olive, Wet, Medium to Soft 6 Clay, No Fractures, Fat, Wet Clays, Colluvium \ k 98.0 18.0 8 10 ." IL BOTTOM OF TRENCH 1 SHEPARJXON ENGINEERING ASSCKXATES. Inc. 1 VISTA SANTA FE L BY DATE TRENCH LOGS CB 5/25/82 1 JOBNO 110175 PLATE NO. 68 1 T 14 Very Dark Olive Brown to Dark Olive, Humid to Moist, Medium to Loose, Clayey Sand & Clay, Topsoil 2 Blue Green, Humid to Moist, Medium to Dense Clay, De1 Mar Formation, Very Fractured, 4 Weathered BOTTOM OF TRENCH T 15 I !. y:. :‘!lsc IVerv Dark brown. Humid to Moist. Medium to -pI;:.:ia::‘j 1 . ’ Loose Clayey Send, Topsoil 27 . Dark Greenish Brown, Moist, Medium to Loose, Clayey Sand & Clay, Colluvium ..\ ,. I 4 4 \ \ICI N IBlue Green. Moist. Medium to Stiff. Clay, Very Fractured - De1 Mar “1 T 13 . . !jM ? I.\$ sc- Red Tan, Humid to Moist, Medium to Loose, .' : : : Silty Clayey Sand, Topsoil 2-.r I SP . ,i Very Light Brown-Gray, Humid to Moist, Medium to Dense, Poorly Graded Clean . *a * I Sand, Torrey Sandstone, Fractured, Massive 4 -:** I * BOTTOM OF TRENCH BOTTOM OF TRENCH VISTA SANTA FE TRENCH LOGS T 16 D M \ \,'I sc Very Dark Brown Black to Dark Greenish Rrown, Humid, Medium to Loose, Clayey \ 2- \ ' \ Sand, Topsoil - Colluvium \ , Very Fractured, Del Mar BOTTOM OF TRENCH T 17 \ \ '\ SC IVery Dark Brown, Humid, Medium to Loose, L \ \K. Clayey Sand, Topsoil 2 -‘\ ! ‘\ sc- I ' CL Dark Brown Green, Moist, Medium to Loose, -t', '\ Clayey Sand & Clay, Colluvium \ 4 - CL Bluish Green, Moist, Medium, Clay \ De1 Mar Weathered, Fractured 6 \\1 I BOTTOM OF TRENCH T 18 \ ' \ \sc Very Dark Brown, Humid, Medium to Loose, 1 '\ '. ' Clayey Sand, Tonaoil 2 -, \ \‘a, , ‘\ ‘bc Very Dark Brown to Green, Moist, Medium to < \ L Loose. Clayey Sand & Clay. Colluvium. \3L Dark Olive Brown, Moist to Wet, Medium Stiff I- Clay > Few Fractures & Voids +.;:y SC lo- '\ Very Light Olive Tan, Moist to Wet, Medium ..? . - \,I\,. Dense, Clayey Sand -., I 12 i,-2,, 108.0 9.7 E SHEPARIMON ENGINEERING ASSCKZATES, Inc. VISTA SANTA FE TRENCH LOGS BY DATE CB 5/25/82 JOENO. 11n17% PLATE NO. 70 - T 19 D M 100.2 25.7 Blue Green, Moist, Medium to Dense, Clay Fractured De1 Mar BOTTOM OF TRENCH T 20 d to Moist, Loose, Silty Clayey Sand BOTTOM OF TRENCH VISTA SANTA FE L L L L L L L L T 21 Dark Brown, Humid, Loose, Clayey Sand Topsoil Pale Tan Green, Humid to Moist, Loose, Sjlty Clayey Sand, Alluvium Redish Tan Brown to Pale Green Brown, Moist, Medium to Loose, Clayey Sand & Clay Colluvium Pale Gray Tan, Humid to Moist, Loose, Clay, Weathered De1 Mar Grayish Blue, Moist, Medium to Dense, Clay De1 Mar Formation BOTTOM OF TRENCH T 22 .: \:... SC Very Dark Greenish Brown, Humid to Moist, Loose, Clayey Sand, Topsoil-Colluvium Clay, De1 Mar, Very Fractured BOTTOKOF TRENCH L . L E SHEPAIUBON ENGINEEZUNG A88ocMTEs. Inc. I BY Pa VISTA SANTA FE TRENCH LOGS DATE YY 5/25/82 No. 110175 PLATE NO. 72 I- T 23 Brown Green, Humid, Loose, Clayey Sand Alluvium Very Pale Green, Humid to Moist, Loose Clayey Silty Sand, Alluvium Pale Green to Brown, Moist, Medium to Loose, Clayey Sand & Clay, Colluvium 'Bluish Gray, Moist, Medium Clay 9 De1 Mar BOTTON OF TRENCH D 100.9 T 24 an Brown, Humid, Loose, Silty Clayey Sand lluvium ery Dark Brown Black, Humid, Medium Stiff, lay, Colluvium, Fractured ery Dark Olive Brown to Dark Olive, Humid o Moist, Medium Stiff, Clay, Colluviun. ery Dark Olive Brown to Dark Olive, Moist to 103.2 et, Medium Dense, Clayey Sand & Clay alluvium BOTTOM OF TRENCH H 18.8 15.6 VISTA SANTA FE SHEPAWN ENGINEXRING A89ocIATE8. Inc. TRENCH LOGS BY CB IXTE 5/25/82 JOBNO 110175 PLATE NO. 73 T 25 Very Dark Brown, Humid, Loose, Clayey Sand Topsoil - Very Fractured 2 -;&‘:$ SC-SN Light Tan, to Light Grayish Blue, Humid to moist, Medium to Loose, Silty Clayey Sand & Clay 4 Brown, Humid to Moist, I+dium to Loose Clay ;;gFi Gray Humid to Moist Medium to berae Y &a&d Clean Sand. be1 Mar Formatjon BOTTOM OF TRENCH T 26 Fractured De1 Mar BOTTOM OF TRENCH T 27 Very Dark Brown to Olive Brown to Dark Olive Tan, Humid to Uoist, Uedium to Loose, Clayey Sand & Clay, Colluvium - Very Fractured,Few Voids BOTTOM OF TRENCH VISTA SANTA FE TRENCH LOGS - T 211 Dark Brown Olive, Humid to Hoist, Medium to Loose, Clayey Sand & Clay, Colluvium, Very Fractured, Few Voids. . BOTTOM OF TRENCH T 29 Sand Older Colluvium Moist, Medium to Loose, Clayey Sand 6 Clay Colluvium, Very Fractured BOTTOM OF TRENCH VISTA SANTA FE TRENCH LOGS T 30 Dark to Very Dark Brown, Humid. Loose, Clayey Sand, Topsoil D w--w------- Dark Brown Olive, Humid to Noist, Medium to Loose, Clayey Sand & Clay, Colluvium Fractured, Few Voids Olive Brown, Moist, Medium to Loose, Clayey Sand & Clay Pale Tan Green, Moist, Medium to Loose, Clayey Sand & Clay Pale Tan Blue, Moist, Medium Stiff, Clay Extremely Weathered De1 Mar BOTTOM OF TRENCH T 31 rwn to Dark Brown to Dark Olive Brown, umid to Moist, Medium to Loose, Clayey and & Clay, Topsoil& Colluvium Very -==*- Few V"l*- 108.7 rown, to Light Brown Green, Hoist, Medium o Loose, Clayey Sand & Clay, Some Minor aliche Deposits M 11.9 Zolluvium - Very Fractured, Few Voids SHEF’ARDSON ENGINEERING Af3WCMTE8. Inc. VISTA SANTA FE BY DATE TRENCH LOGS CB 5/26/82 JOBNO. 110175 PLATE NO. 76 1 $0, ‘:.. ..I., -F * I 2 : . I : :: T 32 Very Dark Brown, Humid, Loose, Clayey Sand Toosoil Dark Olive Brown, Humid to Noist, Nedium Dense. Clayey Sand & Clay, Coiluvium, Very Fractured. Light Tan Green to Olive, Noist, Medium Dense, Clayey Sand & Clay, Colluvium Bluish Gray, Moist, Medium Stiff, Clay Very Weathered De1 Mar BOTTON OF TRENCH T 33 Brown, Humid, Medium to Loose, Silty Clayey Sand, Topsoil .---- ---- ---o-s Humid to Moist, Medium to Loose Clayey Sand, Topsoil Very Light Tan to Yellowish~ Yan, Humid, Hedium to Dense, Poorly Graded Clean Sand D M - Torrey Sandstone, Fractured, Dense, Sandstone Massive 112.0 5.6 BOTTOM OF TRENCH VISTA SANTA FE SHEPARIBON ENGINEERING ASSOCLWES. Inc. BY DATE CB TRENCH LOGS 5126182 mN0. 110175 PLATE NO. 77 - -- 1 1 1 .I 4 ~ 1,~ 1 1 1 1 1 1 1’ 1 1 1 1 I T 34 Brown, Humid, Hedium to Loose. Silty Clayey Sand, Topsoil Red Brown, Humid to Moist, Medium Dense, Clayey Sand, Topsoil Dark Yellow Brown, Humid to Noist, Nedium to Dense, Clayey Sand, Formational Transition Light Yellow Tan, Humid to Moist, Nedium to Dense, Poorly Graded Clean Sand Torrey Sandstone - Fractured, Dense, nassive BOTTOM OF TRENCH T 35 lrery Dark Brown Black, Humid, Loose to Medium Loose, Silty Clayey Sand, Slope Wash, D M 112.7 5.8 ?ery Dark Olive Brown to Olive, Moist, Medium :o Loose. Clayey Sand & Clay, Very Weathered )el Mar 31ue Green, Moist, Medium Stiff, Clay Fractured De1 Mar, Nassive 114.0 12.3 BOTTOM OF TRENCH I E VISTA SANTA FE 1 SHEPARDGON ENGINEXRING ASSGCIATES, Inc. I 1 TRENCH LOGS BY DnTE CB ,5/26/82 .OB NO. 110175 PLATE NO. 78 - 1 .1 1 1 1 1 1 1 1 1 1 .I 1 1 1 T 36 D w Very Dark Brown to Dark Olive Brown, Humid to Moist, Nedium to Loose, Clayey Sand Topsoil Pale Green, Humid to Moist, Medium to Loose, CIavev Sand, De1 Mar-Verv Fractured -tone Green, Humid to Moist, Dense, Poorly Graded Clean Sand, De1 Uar Dark Blue Gray, Humid to Noist, Medium Stiff, Clay 9 Fractured De1 Mar 102.2 BOTTOM OF TRENCH T 37 16.0 Very Dark Brown, Humid, Medium to Loose, Clayey Sand, Topsoil Dark Green to Blue Green to Dark Blue Green, Humid to Noist, Medium Stiff, Clay, Very Fractured De1 Mar Dark Green, Humid to Moist, Hedium to Dense, Clayey Sand 6 Clay, De1 Mar, Massive 115.4 13.3 Dark Blue to Green, Humid to Noist, Medium to Dense, Clay, De1 Mar. Massive I 113-l 14-B BOTTON OF TRENCH 1 E SHEPARDSGN ENGINEERING ASSGCLWE8. Inc. VISTA SANTA FE TRENCH LOGS BY CB DATE 5/26/82 JOBNO. 110175 PLATE NO. 79 - -- ., 2 i? :.";\6 4- T 38 Loose, Clayey Sand & Clay, Colluvium. Dark Brown to Tan Brown, Moist to Wet, Medium to Soft, Clay, Colluvium BOTTOM OF TRENCH T 39 ay, Co1luvil.r; BOTTOM OF TRENCH II M 109.4 13.6 SHEPARLBGN ENGINEERING ASSGCIATES, Inc. 1 VISTA SANTA FE TRENCH LOGS CB I 5126102 NO. 110175 PLATE NO. 80 T 4C Very Dark Brown to Brown Olive Brown, Humid Medium to Loose,Clayey Sand & It Tan Brown, Humid, Loose Poorly Ibraded Clean & Silty Sand, Alluvium Clay, Colluvium - Very Fr=.-**l-nA . A”--... . . Dark Grsyish Brown to Light Greenish Brown, Moist to Wet, Medium to Loose, Clayey Sand 8 Clay, Colluviuv BOTTOM OF TRENCH .J . .J E VISTA SANTA FE SHEPARDSGN ENGINEERING ASSGCUWES. Inc. 1 BY DATE TRENCH LOGS CB 5/26/82 Jc0No I UNIFIED SOILS CLASSIFICATION CHART SOIL DESCRIPTION GROUP SYMBOL TYPICAL NAMES 1. COARSE GRAINED - More than half of material ..- is e than No. 200 sieve size. GRAVELS - More than half of coarse fraction is larger than No. 4 sieve size but smaller than 3”. CLEAN GRAVELS - - GRAVELS WITH FINES (Appreciable amount of fines) .- .- SANDS - More than half of coarse fraction is s than No. 4 sieve size. CLEAN SANDS SANDS WITH FINES (Appreciable amount of fines) II. FINE GRAINED - More than half of material is - smaller than No. 200 sieve size. SILTS AND CLAYS (Liquid Limit less than 50) - SILTS & CLAYS (Liquid Limit greater than 501 MH - . - HIGHLY ORCANlC SOILS GW GP GM GC SW SP SM SC ML CL OL CH OH PT Well graded gravels, gravel-sand mixtures, little or no fines. Poorly graded gravels, gravel sand mixtures, little or no fines. Silty gravels, poorly graded gravel- sand-silt mixtures. Clayey gravels, poorly graded gravel- sand, clay mixtures. Well graded sand, gravelly sands, little or no fines. Poorly graded sands, gravelly sands, little or no fines. Silty sands, poorly graded sand and silt mixtures. Clayey sands, poorly graded sand and clay mixtures. Inorganic silts and very fine sands, rock flour, sandy silt or clayey-silt- sand mixtures with slight plasticity. Inorganic clays of low to medium plasticity, gravelly clays, sandy clays, silty clays, lean clays. Organic silts and organic silty clays of low plasticity. Inorganic silts, micaceous diatomaceous fine sandy or silty soi:, elastic silts. Inorganic clays of high plasticity, fat clays. Organic clays of medium to high plasticity. Peat and other highly organic soils. - - - 6 I LOAD kii/sq.ft. I SEA VISTA SANTA FE - SHEPARDBON ENDINEERING A88ocIms. Inc. B lb ~39’ %I MTE NJ b/22/02 JceNR 110175 PLATE NO. 82 b LOAD kips/sqft. isEA SHEPAFUSON -INEERING m Inc. B 17 @ 7' VISTA SANTA FE 3v MBC ME ~6124182 lmt40. 110175 PLATE NO. 83 - - - 10 9 6 E 5 it, z s 3 s 0 i 2 z s +l 0 -1 -2 -3 -4 -5 t 1 I (Ii/,, ,/,I, I 1 I ,I111 Ill,, / I I / ,I, I I I I ,,/I ill,, I I l/l,, ,,I,, : i I I I I I111111 I I I ! 1 i,I\ ,,,I, 1 I I I Iill I1111 1 1 ,I#\) LOAD kips/sq. ft. SEA VISTA SANTA FE SHEPARLBON EiI’K+INEERU?G A88ocImS. Inc. By MTE CT & MBC 717182 T19 @ 1.5’ - 2.5’ JcaNa 110175 PLATE NO. 84 .- - - - 6 t , , 1 I I,,,, 1,111 I , I ,I<, I1111 I I1 1 1 1 I I1111 III11 t I 1 I III, I III1 I I,, I I ,I., I ILII I , I ,I., I1111 I ,,.I, 01 0.5 1.0 5 10 50 LOAD kim/aa.ft. SEA VISTA SANTA FE SHEPAFUSON ENGINEERING AssocIA!rEa Inc. By MBC DATE B 19 @ 23' b/25/02 Jmrm 110175 PLATE NO. 79 - .~.~ ..- - .~ - .- .- .- - - - I - , I ,,I I 0.1 0.5 1.0 5 10 50 I LOAD kips/sq.ft. CSEA VISTA SANTA FE SHEPARDBON ENGINEWING W Inc. sv MBC lMTE b/25/02 B 22 @ 26’ I Na 110175 I PLATE NO. 86 - 0 ‘i -1 iti b 0 0’ 2 -- s 0 ij zi 0 -3 -4 LOAD kif%+.ft. SEA VISTA SANTA FE - SHEPARLBON EK;INEERIIW ASSOCIATES. Inc. SY MTE CT & MBC l/7/82 - T23 @ 4.5' - 5.5' 311Bta. 110175 PLATE NO. 87 - - - - - -6 I I I I I I 1 I I I I, I I / I I 1 , , I I ,I/ ’ II, I I I ,I I I /,I 1 I LOAD kipa/sq.ft. SEA ’ VISTA SANTA FE SHEPARDBON EIWXNEERING ASWCIATES. Inc. B30 43 21' By CT & MBC KaN0 110175 717182 I PLATE NO. 88 - - .- - .- ..,- - - - - - - - .- .- !K-J PANSION TEST RESULTS INITIAL DENSITYtPCF) SAMPLE SAMPLE CONDITION INITIAL MC.(%) I INITIAL DENSITY(PCF) FINAL M.C. (*/.I I NORMAL STRESS (PSD EXPANSION (‘1.1 I SHEPARDSON ENGINEERING ASSOCIATES. Inc. VISTA SANTA FE PI CT 1 DATE ,7/7/82 mm ~0~110175 PLATE NO. RQ - -. -~ .-~ - -~ - .- -~ -~ -~ -~. -~ _- : -~ -.~ MAXIMUM DENSITY & OPTIMUM MOISTURE CONTENT A ST ML??? Met hod: _____ ff, .,, B33 @ 13'-15' T33 @ 7'43 SEA a VISTA SANTA FE SHEPARDSON EX’IGINEEXING ASSCMJATES, Inc. DY CT DATE J/7/82 JOB ~0. 110175 PLATE NO. 90 DIRECT SHEAR TEST RESULTS &Em ’ VISTA SANTA FE SHEPARDSON ENGINEERING ASSOCIATES, Inc. N CT DATE l/7/02 1~~ JOB No. 110175 I PLATE NO. 91